Fiber-delivered laser-induced dynamic light system

ABSTRACT

The present disclosure provides an apparatus for generating fiber delivered laser-induced dynamically controlled white light emission. The apparatus includes a laser diode unit for generating a laser electromagnetic radiation with a blue emission in a range from 395 nm to 490 nm that is delivered by an optical fiber. The apparatus further includes a dynamic phosphor unit configured to receive the laser exited from the optical fiber and controllably deflect a beam focused by a first optics sub-unit to a surface spot on a phosphor plate to produce a white light emission. Additionally, and the dynamic phosphor unit includes a second optics sub-unit configured to collect the white light emission and to project to a far field. Furthermore, the apparatus includes an electronics control unit comprising a laser diode driver and a MEMS driver for respectively control the laser diode unit and the dynamic phosphor unit in mutually synchronized manner.

CROSS-REFERENCES TO RELATED APPLICATIONS

This present application is a division of U.S. application Ser. No. 16/230,365, filed Dec. 21, 2018, the entire contents of which are incorporated herein by reference in its entirety for all purposes.

BACKGROUND

In the late 1800's, Thomas Edison invented the light bulb. The conventional light bulb, commonly called the “Edison bulb,” has been used for over one hundred years for a variety of applications including lighting and displays. The conventional light bulb uses a tungsten filament enclosed in a glass bulb sealed in a base, which is screwed into a socket. The socket is coupled to an AC power or DC power source. The conventional light bulb can be found commonly in houses, buildings, and outdoor lightings, and other areas requiring light or displays. Unfortunately, drawbacks exist with the conventional light bulb:

-   -   The conventional light bulb dissipates more than 90% of the         energy used as thermal energy.     -   The conventional light bulb routinely fails due to thermal         expansion and contraction of the filament element.     -   The conventional light bulb emits light over a broad spectrum,         much of which is not perceived by the human eye.     -   The conventional light bulb emits in all directions, which is         undesirable for applications requiring strong directionality or         focus, e.g. projection displays, optical data storage, etc.

To overcome some of the drawbacks of the conventional light bulb, several alternatives have been developed including fluorescent lamps, Mercury vapor lamps, sodium vapor lamps, other high-intensity discharge (HID) lamps, gas discharge lamps such as neon lamps, among others. These lamp technologies in general suffer from similar problems to Edison lamps as well as having their own unique drawbacks. For example, fluorescent lamps require high voltages to start, which can be in the range of a thousand volts for large lamps, and also emit highly non-ideal spectra that are dominated by spectral lines.

In the past decade, solid state lighting has risen in importance due to several key advantages it has over conventional lighting technology. Solid state lighting is lighting derived from semiconductor devices such as diodes which are designed and optimized to emit photons. Due to the high efficiency, long lifetimes, low cost, and non-toxicity offered by solid state lighting technology, light emitting diodes (LED) have rapidly emerged as the illumination technology of choice. An LED is a two-lead semiconductor light source typically based on a p-i-n junction diode, which emits electromagnetic radiation when activated. The emission from an LED is spontaneous and is typically in a Lambertian pattern. When a suitable voltage is applied to the leads, electrons and holes recombine within the device releasing energy in the form of photons. This effect is called electroluminescence, and the color of the light is determined by the energy band gap of the semiconductor.

Appearing as practical electronic components in 1962 the earliest LEDs emitted low-intensity infrared light. Infrared LEDs are still frequently used as transmitting elements in remote-control circuits, such as those in remote controls for a wide variety of consumer electronics. The first visible-light LEDs were also of low intensity, and limited to red. Modern LEDs are available across the visible, ultraviolet, and infrared wavelengths, with very high brightness.

The earliest blue and violet gallium nitride (GaN)-based LEDs were fabricated using a metal-insulator-semiconductor structure due to a lack of p-type GaN. The first p-n junction GaN LED was demonstrated by Amano et al. using the LEEBI treatment to obtain p-type GaN in 1989. They obtained the current-voltage (I-V) curve and electroluminescence of the LEDs, but did not record the output power or the efficiency of the LEDs. Nakamura et al. demonstrated the p-n junction GaN LED using the low-temperature GaN buffer and the LEEBI treatment in 1991 with an output power of 42 μW at 20 mA. The first p-GaN/n-InGaN/n-GaN DH blue LEDs were demonstrated by Nakamura et al. in 1993. The LED showed a strong band-edge emission of InGaN in a blue wavelength regime with an emission wavelength of 440 nm under a forward biased condition. The output power and the EQE were 125 μW and 0.22%, respectively, at a forward current of 20 mA. In 1994, Nakamura et al. demonstrated commercially available blue LEDs with an output power of 1.5 mW, an EQE of 2.7%, and the emission wavelength of 450 nm. On Oct. 7, 2014, the Nobel Prize in Physics was awarded to Isamu Akasaki, Hiroshi Amano and Shuji Nakamura for “the invention of efficient blue light-emitting diodes which has enabled bright and energy-saving white light sources” or, less formally, LED lamps.

By combining GaN-based LEDs with wavelength converting materials such as phosphors, solid-state white light sources were realized. This technology utilizing GaN-based LEDs and phosphor materials to produce white light is now illuminating the world around us as a result of the many advantages over incandescent light sources including lower energy consumption, longer lifetime, improved physical robustness, smaller size, and faster switching. LEDs are now used in applications as diverse as aviation lighting, automotive headlamps, advertising, general lighting, traffic signals, and camera flashes. LEDs have allowed new text, video displays, and sensors to be developed, while their high switching rates can be very useful in communications technology. LEDs, however, are not the only solid-state light source and may not be preferable light sources for certain lighting applications. Alternative solid state light sources utilizing stimulated emission, such as laser diodes (LDs) or super-luminescent light emitting diodes (SLEDs), provide many unique features advantageously over LEDs.

In 1960, the laser was demonstrated by Theodore H. Maiman at Hughes Research Laboratories in Malibu. This laser utilized a solid-state flash lamp-pumped synthetic ruby crystal to produce red laser light at 694 nm. Early visible laser technology comprised lamp pumped infrared solid state lasers with the output wavelength converted to the visible using specialty crystals with nonlinear optical properties. For example, a green lamp pumped solid state laser had 3 stages: electricity powers lamp, lamp excites gain crystal which lases at 1064 nm, 1064 nm goes into frequency conversion crystal which converts to visible 532 nm. The resulting green and blue lasers were called “lamped pumped solid state lasers with second harmonic generation” (LPSS with SHG) had wall plug efficiency of ˜1%, and were more efficient than Ar-ion gas lasers, but were still too inefficient, large, expensive, fragile for broad deployment outside of specialty scientific and medical applications. To improve the efficiency of these visible lasers, high power diode (or semiconductor) lasers were utilized. These “diode pumped solid state lasers with SHG” (DPSS with SHG) had 3 stages: electricity powers 808 nm diode laser, 808 nm excites gain crystal, which lases at 1064 nm, 1064 nm goes into frequency conversion crystal which converts to visible 532 nm. As high-power laser diodes evolved and new specialty SHG crystals were developed, it became possible to directly convert the output of the infrared diode laser to produce blue and green laser light output. These “directly doubled diode lasers” or SHG diode lasers had 2 stages: electricity powers 1064 nm semiconductor laser, 1064 nm goes into frequency conversion crystal which converts to visible 532 nm green light. These lasers designs are meant to improve the efficiency, cost and size compared to DPSS-SHG lasers, but the specialty diodes and crystals required make this challenging today.

Solid-state laser light sources, due to the narrowness of their spectra which enables efficient spectral filtering, high modulation rates, and short carrier lifetimes, smaller in size, and far greater surface brightness compared to LEDs, can be more preferable as visible light sources as a means of transmitting information with high bandwidth in many applications including lighting fixtures, lighting systems, displays, projectors and the like. Advancements of new GaN-based blue laser technology based on improved processes have substantially reduced manufacture cost and opened opportunities for utilizing the modulated laser signal and the light spot directly to measure and or interact with the surrounding environment, transmit data to other electronic systems, and respond dynamically to inputs from various sensors. Such applications are herein referred to as “smart lighting” applications to be disclosed throughout the specification herein.

SUMMARY

The present invention provides a fiber-delivered phosphor-emitted white light system and method of making the same. Merely by examples, the invention provides laser pumped phosphor light sources from gallium and nitrogen containing laser diodes, white light source integrated with a fiber attached phosphor in packaging and laser pump-light delivery configuration. The invention is applicable to many applications including static lighting devices and methods, dynamic lighting devices and methods, LIDAR, LiFi, and visible light communication devices and methods, and various combinations of above in applications of general lighting, commercial lighting and display, automotive lighting and communication, defense and security, industrial processing, and internet communications, and others.

Specific embodiments of this invention employ a transferred gallium and nitrogen containing material process for fabricating laser diodes or other gallium and nitrogen containing devices (as shown in U.S. Pat. Nos. 9,666,677 and 9,379,525, filed by one of inventors of this application) enabling benefits over conventional fabrication technologies.

In some embodiments, beam shaping elements such as MEMS scanning mirrors, and communications triggered by integrated sensor feedback are employed to generate smart laser lighting. The smart laser lighting can be combined with LIDAR technology for enhanced system functionality and/or enhanced LIDAR function. Specific embodiments of this invention employ a transferred gallium and nitrogen containing material process (U.S. Pat. Nos. 9,666,677 and 9,379,525) for fabricating laser diodes or other gallium and nitrogen containing devices enabling benefits over conventional fabrication technologies.

Optionally, the phosphor material used in the fiber-delivered smart laser lighting system is comprised of a ceramic yttrium aluminum garnet (YAG) doped with Ce or a single crystal YAG doped with Ce or a powdered YAG comprising a binder material. The phosphor has an optical conversion efficiency of greater than 50 lumen per optical watt, greater than 100 lumen per optical watt, greater than 200 lumen per optical watt, or greater than 300 lumen per optical watt.

Optionally, a waveguide element is used to transport the laser excitation pump source to the remote wavelength converter element such as a phosphor element. In a preferred embodiment, the transport waveguide is an optical fiber wherein the optical fiber could be comprised of a single mode fiber (SMF) or a multi-mode fiber (MMF), with core diameters ranging from about 1 um to 10 um, about 10 um to 50 um, about 50 um to 150 um, about 150 um to 500 um, about 500 um to 1 mm, or greater than 1 mm. The optical core material may consist of a glass such as silica glass wherein the silica glass could be doped with various constituents and have a predetermined level of hydroxyl groups (OH) for an optimized propagation loss characteristic. The glass fiber material may also be comprised of a fluoride glass, a phosphate glass, or a chalcogenide glass. In an alternative embodiment, a plastic optical fiber is used to transport the laser pump light.

Optionally, the phosphor material is configured to operate in a mode selected from a reflective mode, a transmissive mode, and a combination of a reflective mode and a transmissive mode in association with receiving the first laser beam with the first peak wavelength to excite the emission with the second peak wavelength.

Optionally, the integrated package includes the wavelength conversion member configured as a remote pumped phosphor and an optical fiber to guide the laser beam from the gallium and nitrogen containing laser diode to the remote pumped phosphor.

Optionally, the at least one gallium and nitrogen containing laser diode includes multiple laser diodes such as 2 laser diodes, 3 laser diodes, or 4 laser diodes to generate 2 laser beams, 3 laser beams, or 4 laser beams, respectively. The multiple laser beams form an excitation spot on the wavelength conversion member.

Optionally, each of the multiple laser diodes is characterized by one of multiple first peak wavelengths in 420 nm to 485 nm blue color range. The multiple first peak wavelengths result in an improved color quality of the white light.

Optionally, the wavelength conversion member includes a first phosphor material configured to be excited by the first laser beam with the first peak wavelength to produce a first emission of a second peak wavelength and a second phosphor material configured to be excited by the laser beam to produce a second emission with a third peak wavelength.

Optionally, the gallium and nitrogen containing laser diode is characterized by the first laser beam with the first peak wavelength in violet color range. The first phosphor material is characterized by the first emission with the second peak wavelength in blue color range. The second phosphor material is characterized by the second emission with the third wavelength in yellow color range. The white light is comprised of at least the first emission and the second emission.

Optionally, the beam projector includes a MEMS or other micro-controlled scanner or display module, micro-mirror, micro-lens, configured to dynamically scan a beam of the sensing light signal across the remote target object.

Optionally, the blue laser light is characterized by high power levels in one range selected from 1 mW to 10 mW, 10 mW to 100 mW, 100 mW to 1 W, and 1 W to 10 W capable of sensing and mapping the remote target object under damp condition with relative humidity level in each of following ranges of greater than 25%, greater than 50%, greater than 75%, and greater than 100%.

In a specific embodiment, the present invention provides a dynamic light system. The dynamic light system includes a laser driver and one or more laser devices each having a gallium and nitrogen containing emitting region driven by the laser driver to emit a laser electromagnetic radiation characterized by a first wavelength ranging from 395 nm to 490 nm. The dynamic light system further includes one or more beam collimation elements configured to confine the laser electromagnetic radiation. Additionally, the dynamic light system includes a waveguide device comprising an adaptor member, a transport member, and a light head member. The adaptor member is physically aligned to couple the laser electromagnetic radiation into the transport member and deliver the laser electromagnetic radiation through a predetermined length to the light head member disposed at a distal end of the transport member. The dynamic light system further includes a dynamic beam controlling element disposed in a path of incoming laser electromagnetic radiation and configured to redirect a beam of the laser electromagnetic radiation to multiple paths. Furthermore, the dynamic light system includes one or more wavelength converting elements disposed to have at least one element being aligned in one of the multiple paths to receive the beam of laser electromagnetic radiation. The respective one element is configured to convert the beam of the laser electromagnetic radiation to an induced emission with a second wavelength longer than the first wavelength. A mixture of the induced emission and a portion of the laser electromagnetic radiation produces a white light emission. Furthermore, the dynamic light system includes a beam projection element configured to utilize the white light emission as a white light source.

In another specific embodiment, the present invention provides a fiber-delivered laser-induced dynamic light system. The dynamic light system includes a laser diode unit including one or more laser devices for generating a laser electromagnetic radiation with a blue emission in a range from 395 nm to 490 nm. The laser diode unit also includes one or more beam-conditioning optics for collimating the laser electromagnetic radiation. The laser diode unit further includes a fiber terminal adaptor configured to couple the laser electromagnetic radiation to an optical fiber. Additionally, the dynamic light system includes a dynamic phosphor unit including a bi-directional MEMS mirror capable of scanning in an x and y direction. The MEMS is configured to receive the laser electromagnetic radiation exited from the optical fiber and controllably deflect a beam of the laser electromagnetic radiation to desirable directions. The dynamic phosphor unit further includes a first optics sub-unit configured to focus deflected beam of laser electromagnetic radiation to a surface spot on a phosphor plate to produce a white light emission. Furthermore, the dynamic phosphor unit includes a second optics sub-unit configured to collect a white light emission from the phosphor plate and to shape and project the white light emission of a far field. Moreover, the dynamic light system includes an electronics control unit including a laser diode driver and a MEMS driver mutually synchronized. The laser diode driver is configured to drive each of the multiple laser devices in the laser diode unit to generate the respective laser electromagnetic radiation. The MEMS driver is configured to control the MEMS mirror in the dynamic phosphor unit to scan the beam of laser electromagnetic radiation to various surface spots on the phosphor plate to produce various white light emissions respectively at various times.

In yet another specific embodiment, the present invention provides a fiber-delivered laser-induced dynamic white light source for auto headlight. The dynamic white light source includes a laser module packaged in a metal case plugged to a circuit board, the metal case enclosing a support member, at least one laser diode device configured to mount on the support member and to emit a laser beam characterized by a wavelength ranging from 395 nm to 490 nm, and a collimating lens configured to guide the laser beam to an output port. Additionally, the dynamic white light source includes a focus lens coupled to the output port from outside the metal case to receive and confine the laser beam. Furthermore, the dynamic white light source includes a fiber assembly embedding an optical fiber having a first end section coupled to the output port with alignment to receive the laser beam from the focus lens and deliver the laser beam through the optical fiber to a second end section. Moreover, the dynamic white light source includes a light head member disposed remotely in an auto headlight module holding a dynamic beam control element coupled to receive the laser beam exited from the second end section of the optical fiber and to dynamically scan the laser beam over a predetermined surface area of a phosphor material. The laser beam forms an angle of incidence in a range from 5 degrees to 90 degrees between the laser beam and a direction parallel to the surface of the phosphor material to create a spot ranging from 50 μm to 5 mm dynamically scanning from one pixelated region to another of the surface of the phosphor material. The laser beam in the spot induces a phosphor-excited emission which is partially mixed with the laser beam to produce a white light emission. The white light emission dynamically outputting from one pixelated region of the phosphor material are manipulated by a secondary optics to become a dynamic projection light source of the auto headlight module.

Merely by way of example, the present invention can be applied to applications such as white lighting, white spot lighting, flash lights, automotive applications, automobile headlights or other lighting and communications functions, autonomous vehicles, all-terrain vehicle lighting, light sources used in recreational sports such as biking, surfing, running, racing, boating, light sources used for drones, planes, robots, other mobile or robotic applications, autonomous devices such as land, sea, or air vehicles and technology, safety, counter measures in defense applications, multi-colored lighting, lighting for flat panels, medical, metrology, beam projectors and other displays, high intensity lamps, spectroscopy, entertainment, theater, music, and concerts, analysis fraud detection and/or authenticating, tools, water treatment, laser dazzlers, targeting, communications, LiFi, visible light communications (VLC), sensing, detecting, distance detecting, Light Detection And Ranging (LIDAR), transformations, transportations, leveling, curing and other chemical treatments, heating, cutting and/or ablating, pumping other optical devices, other optoelectronic devices and related applications, and source lighting and the like.

BRIEF DESCRIPTION OF THE FIGURES

The following drawings are merely examples for illustrative purposes according to various disclosed embodiments and are not intended to limit the scope of the present invention.

FIG. 1 is a schematic diagram showing dependence of internal quantum efficiency in a laser diode on carrier concentration in the light emitting layers of the device.

FIG. 2 is a plot of external quantum efficiency as a function of current density for a high-power blue laser diode compared to the high-power blue light emitting diode.

FIG. 3 is a simplified schematic diagram of a laser diode formed on a gallium and nitrogen containing substrate with the cavity aligned in a direction ended with cleaved or etched mirrors according to some embodiments of the present invention.

FIG. 4 is a cross-sectional view of a laser device according to an embodiment of the present invention.

FIG. 5 is a schematic diagram illustrating a chip on submount (CoS) based on a conventional laser diode formed on gallium and nitrogen containing substrate technology according to an embodiment of the present invention.

FIG. 6 is a schematic representation of the die expansion process with selective area bonding according to some embodiments of the present invention.

FIG. 7 is a schematic diagram illustrating a CoS based on lifted off and transferred epitaxial gallium and nitrogen containing layers according to an embodiment of this present invention.

FIG. 8A is a functional block diagram for a laser-based white light source containing a blue pump laser and a wavelength converting element according to an embodiment of the present invention.

FIG. 8B is a functional block diagram for a laser-based white light source containing multiple blue pump lasers and a wavelength converting element according to another embodiment of the present invention.

FIG. 9A is a functional block diagram for a laser-based fiber-delivered white light source according to an embodiment of the present invention.

FIG. 9B is a functional block diagram for a laser-based fiber-delivered white light source according to another embodiment of the present invention.

FIG. 9C is a functional block diagram for a multi-laser-based fiber-delivered white light source according to yet another embodiment of the present invention.

FIG. 10A is a simplified diagram illustrating a plurality of laser bars configured with optical combiners according to embodiments of the present invention.

FIG. 10B is a schematic diagram of an enclosed free space laser module according to a specific embodiment of the present invention.

FIG. 10C is a schematic diagram of an enclosed free space multi-chip laser module with an extended delivery fiber plus phosphor converter according to another specific embodiment of the present invention.

FIG. 11 is a perspective view of a fiber-delivered white light source including a general laser package and a light head member linked each other via a fiber assembly according to an embodiment of the present invention.

FIG. 12 is a top view of the general laser package of FIG. 11 according to the embodiment of the present invention.

FIG. 13 is a top view of interior elements of the general laser package of FIG. 12 including a blue-laser module mounted on a circuit board according to the embodiment of the present invention.

FIG. 14 is a top view of the blue-laser module with opened lid according to an embodiment of the present invention.

FIG. 15 is a perspective view of the blue-laser module according to the embodiment of the present invention.

FIG. 16 is (A) a top view of a general laser package, (B) a top view of interior elements of the general laser package including a blue-laser module, and (C) a top view of the blue-laser module according to another embodiment of the present invention.

FIG. 17 is a partial cross-sectional view of a fiber assembly according to an embodiment of the present invention.

FIG. 18 is a partial cross-sectional view of a fiber assembly according to another embodiment of the present invention.

FIG. 19 is a perspective view of the light head member of FIG. 11 according to an embodiment of the present invention.

FIG. 20 shows an exemplary diagram of a fiber coupling joint made by mechanical butt coupler according to an embodiment of the present invention.

FIG. 21A is a block diagram of a dynamic light system based on fiber-delivered laser induced white light source according to an embodiment of the present invention.

FIG. 21B is a block diagram of a dynamic light system based on fiber-delivered multi-laser-induced white light source according to another embodiment of the present invention.

FIG. 22 is a block diagram of a dynamic light system based on fiber-delivered laser-induced white light source according to an embodiment of the present invention.

FIG. 23 is a schematic diagram of a dynamic phosphor unit according to an embodiment of the present invention.

FIG. 24 is a perspective view of a MEMS mirror package used as dynamic beam controlling elements according to an embodiment of the present invention.

FIG. 25 is a schematic diagram of a multichip laser diode unit according to an embodiment of the present invention.

FIG. 26 is a schematic diagram of a fiber-delivered dynamic white light system for street pole light application according to an embodiment of the present invention.

FIG. 27 is a schematic diagram of a fiber-delivered dynamic white light system for auto light application according to an embodiment of the present invention.

DETAILED DESCRIPTION

The present invention provides a fiber-delivered phosphor-emitted white light system and method of making the same. Merely by examples, the invention provides laser pumped phosphor light sources from gallium and nitrogen containing laser diodes, white light source integrated with a fiber attached phosphor in packaging and pump-light delivering configuration. The invention is applicable to many applications including dynamic lighting devices and methods, LIDAR, LiFi, and visible light communication devices and methods, and various combinations of above in applications of general lighting, commercial lighting and display, automotive lighting and communication, defense and security, industrial processing, and internet communications, and others.

As background, while LED-based light sources offer great advantages over incandescent based sources, there are still challenges and limitations associated with LED device physics. The first limitation is the so called “droop” phenomenon that plagues GaN based LEDs. The droop effect leads to power rollover with increased current density, which forces LEDs to hit peak external quantum efficiency at very low current densities in the 10-200 A/cm² range. FIG. 1 shows a schematic diagram of the relationship between internal quantum efficiency [IQE] and carrier concentration in the light emitting layers of a light emitting diode [LED] and light-emitting devices where stimulated emission is significant such as laser diodes [LDs] or super-luminescent LEDs. IQE is defined as the ratio of the radiative recombination rate to the total recombination rate in the device. At low carrier concentrations Shockley-Reed-Hall recombination at crystal defects dominates recombination rates such that IQE is low. At moderate carrier concentrations, spontaneous radiative recombination dominates such that IQE is relatively high. At high carrier concentrations, non-radiative auger recombination dominates such that IQE is again relatively low. In devices such as LDs or SLEDs, stimulated emission at very high carrier densities leads to a fourth regime where IQE is relatively high. FIG. 2 shows a plot of the external quantum efficiency [EQE] for a typical blue LED and for a high power blue laser diode. EQE is defined as the product of the IQE and the fraction of generated photons that are able to exit the device. While the blue LED achieves a very high EQE at very low current densities, it exhibits very low EQE at high current densities due to the dominance of auger recombination at high current densities. The LD, however, is dominated by stimulated emission at high current densities, and exhibits very high EQE. At low current densities, the LD has relatively poor EQE due to re-absorption of photons in the device. Thus, to maximize efficiency of the LED based light source, the current density must be limited to low values where the light output is also limited. The result is low output power per unit area of LED die [flux], which forces the use large LED die areas to meet the brightness requirements for most applications. For example, a typical LED based light bulb will require 3 mm² to 30 mm² of epi area.

A second limitation of LEDs is also related to their brightness, more specifically it is related to their spatial brightness. A conventional high brightness LED emits ˜1 W per mm² of epi area. With some advances and breakthrough this can be increased up to 5-10× to 5-10 W per mm² of epi area. Finally, LEDs fabricated on conventional c-plane GaN suffer from strong internal polarization fields, which spatially separate the electron and hole wave functions and lead to poor radiative recombination efficiency. Since this phenomenon becomes more pronounced in InGaN layers with increased indium content for increased wavelength emission, extending the performance of UV or blue GaN-based LEDs to the blue-green or green regime has been difficult.

An exciting new class of solid-state lighting based on laser diodes is rapidly emerging. Like an LED, a laser diode is a two-lead semiconductor light source that that emits electromagnetic radiation. However, unlike the output from an LED that is primarily spontaneous emission, the output of a laser diode is comprised primarily of stimulated emission. The laser diode contains a gain medium that functions to provide emission through the recombination of electron-hole pairs and a cavity region that functions as a resonator for the emission from the gain medium. When a suitable voltage is applied to the leads to sufficiently pump the gain medium, the cavity losses are overcome by the gain and the laser diode reaches the so-called threshold condition, wherein a steep increase in the light output versus current input characteristic is observed. At the threshold condition, the carrier density clamps and stimulated emission dominates the emission. Since the droop phenomenon that plagues LEDs is dependent on carrier density, the clamped carrier density within laser diodes provides a solution to the droop challenge. Further, laser diodes emit highly directional and coherent light with orders of magnitude higher spatial brightness than LEDs. For example, a commercially available edge emitting GaN-based laser diode can reliably produce about 2 W of power in an aperture that is 15 μm wide by about 0.5 μm tall, which equates to over 250,000 W/mm². This spatial brightness is over 5 orders of magnitude higher than LEDs or put another way, 10,000 times brighter than an LED.

Based on essentially all the pioneering work on GaN LEDs, visible laser diodes based on GaN technology have rapidly emerged over the past 20 years. Currently the only viable direct blue and green laser diode structures are fabricated from the wurtzite AlGaInN material system. The manufacturing of light emitting diodes from GaN related materials is dominated by the heteroepitaxial growth of GaN on foreign substrates such as Si, SiC and sapphire. Laser diode devices operate at such high current densities that the crystalline defects associated with heteroepitaxial growth are not acceptable. Because of this, very low defect-density, free-standing GaN substrates have become the substrate of choice for GaN laser diode manufacturing. Unfortunately, such bulk GaN substrates are costly and not widely available in large diameters. For example, 2″ diameter is the most common laser-quality bulk GaN c-plane substrate size today with recent progress enabling 4″ diameter, which are still relatively small compared to the 6″ and greater diameters that are commercially available for mature substrate technologies. Further details of the present invention can be found throughout the present specification and more particularly below.

Additional benefits are achieved over pre-existing techniques using the present invention. In particular, the present invention enables a cost-effective laser-based remotely delivered white light source. In a specific embodiment, the present optical device can be manufactured in a relatively simple and cost-effective manner. Depending upon the embodiment, the present apparatus and method can be manufactured using conventional materials and/or methods according to one of ordinary skill in the art. In some embodiments of this invention the gallium and nitrogen containing laser diode source is based on c-plane gallium nitride material and in other embodiments the laser diode is based on nonpolar or semipolar gallium and nitride material. In one embodiment the white source is configured from a laser chip on submount (CoS) with the laser light being delivered by a waveguide to a phosphor supported on a remotely disposed submount and/or a remote support member to form a remotely-delivered white light source. In some embodiments, the waveguide is a semiconductor waveguide integrated on a intermediate submount coupled with the CoS. In some embodiments the waveguide includes an optical fiber disposed substantially free in space or in custom layout, making the white light source a fiber-delivered white light source. In some embodiments the white light source includes beam collimation and focus elements to couple the laser light into the waveguide or fiber. In some embodiments, the white light source includes multiple laser chips either independently or co-packaged in a same package case and the phosphor member are supported in a separate submount heatsink packaged in a remote case. In some embodiments there could be additional beam shaping optical elements included for shaping or controlling the white light out of the phosphor.

In various embodiments, the laser device and phosphor device are separately packaged or mounted on respective support member and the phosphor materials are operated in a reflective mode to result in a white emitting laser-based light source. In additional various embodiments, the electromagnetic radiation from the laser device is remotely coupled to the phosphor device through means such as free space coupling or coupling with a waveguide such as a fiber optic cable or other solid waveguide material, and wherein the phosphor materials are operated in a reflective mode to result in a white emitting laser-based light source. Merely by way of example, the invention can be applied to applications such as white lighting, white spot lighting, flash lights, automobile headlights, all-terrain vehicle lighting, flash sources such as camera flashes, light sources used in recreational sports such as biking, surfing, running, racing, boating, light sources used for drones, planes, robots, other mobile or robotic applications, safety, counter measures in defense applications, multi-colored lighting, lighting for flat panels, medical, metrology, beam projectors and other displays, high intensity lamps, spectroscopy, entertainment, theater, music, and concerts, analysis fraud detection and/or authenticating, tools, water treatment, laser dazzlers, targeting, communications, LiFi, visible light communications (VLC), sensing, detecting, distance detecting, Light Detection And Ranging (LIDAR), transformations, autonomous vehicles, transportations, leveling, curing and other chemical treatments, heating, cutting and/or ablating, pumping other optical devices, other optoelectronic devices and related applications, and source lighting and the like.

Laser diodes are ideal as phosphor excitation sources. With a spatial brightness (optical intensity per unit area) greater than 10,000 times higher than conventional LEDs and the extreme directionality of the laser emission, laser diodes enable characteristics unachievable by LEDs and other light sources. Specifically, since the laser diodes output beams carrying over 1 W, over 5 W, over 10 W, or even over 100 W can be focused to very small spot sizes of less than 1 mm in diameter, less than 500 μm in diameter, less than 100 μm in diameter, or even less than 50 μm in diameter, power densities of over 1 W/mm², 100 W/mm², or even over 2,500 W/mm² can be achieved. When this very small and powerful beam of laser excitation light is incident on a phosphor material the ultimate point source of white light can be achieved. Assuming a phosphor conversion ratio of 200 lumens of emitted white light per optical watt of excitation light, a 5 W excitation power could generate 1000 lumens in a beam diameter of 100 μm, or 50 μm, or less. Such a point source is game changing in applications such as spotlighting or range finding where parabolic reflectors or lensing optics can be combined with the point source to create highly collimated white light spots that can travel drastically higher distances than ever possible before using LEDs or bulb technology.

In some embodiments of the present invention the gallium and nitrogen containing light emitting device may not be a laser device, but instead may be configured as a superluminescent diode or superluminescent light emitting diode (SLED) device. For the purposes of this invention, a SLED device and laser diode device can be used interchangeably. A SLED is similar to a laser diode as it is based on an electrically driven junction that when injected with current becomes optically active and generates amplified spontaneous emission (ASE) and gain over a wide range of wavelengths. When the optical output becomes dominated by ASE there is a knee in the light output versus current (LI) characteristic wherein the unit of light output becomes drastically larger per unit of injected current. This knee in the LI curve resembles the threshold of a laser diode, but is much softer. The advantage of a SLED device is that SLED it can combine the unique properties of high optical emission power and extremely high spatial brightness of laser diodes that make them ideal for highly efficient long throw illumination and high brightness phosphor excitation applications with a broad spectral width of (>5 nm) that provides for an improved eye safety and image quality in some cases. The broad spectral width results in a low coherence length similar to an LED. The low coherence length provides for an improved safety such has improved eye safety. Moreover, the broad spectral width can drastically reduce optical distortions in display or illumination applications. As an example, the well-known distortion pattern referred to as “speckle” is the result of an intensity pattern produced by the mutual interference of a set of wavefronts on a surface or in a viewing plane. The general equations typically used to quantify the degree of speckle are inversely proportional to the spectral width. In the present specification, both a laser diode (LD) device and a superluminescent light emitting diode (SLED) device are sometime simply referred to “laser device”.

A gallium and nitrogen containing laser diode (LD) or super luminescent light emitting diode (SLED) may comprise at least a gallium and nitrogen containing device having an active region and a cavity member and are characterized by emitted spectra generated by the stimulated emission of photons. In some embodiments a laser device emitting red laser light, i.e. light with wavelength between about 600 nm to 750 nm, are provided. These red laser diodes may comprise at least a gallium phosphorus and arsenic containing device having an active region and a cavity member and are characterized by emitted spectra generated by the stimulated emission of photons. The ideal wavelength for a red device for display applications is ˜635 nm, for green ˜530 nm and for blue 440-470 nm. There may be tradeoffs between what colors are rendered with a display using different wavelength lasers and also how bright the display is as the eye is more sensitive to some wavelengths than to others.

In some embodiments according to the present invention, multiple laser diode sources are configured to excite the same phosphor or phosphor network. Combining multiple laser sources can offer many potential benefits according to this invention. First, the excitation power can be increased by beam combining to provide a more powerful excitation spit and hence produce a brighter light source. In some embodiments, separate individual laser chips are configured within the laser-phosphor light source. By including multiple lasers emitting 1 W, 2 W, 3 W, 4 W, 5 W or more power each, the excitation power can be increased and hence the source brightness would be increased. For example, by including two 3 W lasers exciting the same phosphor area, the excitation power can be increased to 6 W for double the white light brightness. In an example where about 200 lumens of white are generated per 1 watt of laser excitation power, the white light output would be increased from 600 lumens to 1200 lumens. Beyond scaling the power of each single laser diode emitter, the total luminous flux of the white light source can be increased by continuing to increase the total number of laser diodes, which can range from 10 s, to 100 s, and even to 1000 s of laser diode emitters resulting in 10 s to 100 s of kW of laser diode excitation power. Scaling the number of laser diode emitters can be accomplished in many ways such as including multiple lasers in a co-package, spatial beam combining through conventional refractive optics or polarization combining, and others. Moreover, laser diode bars or arrays, and mini-bars can be utilized where each laser chip includes many adjacent laser diode emitters. For example, a bar could include from 2 to 100 laser diode emitters spaced from about 10 microns to about 400 microns apart. Similarly, the reliability of the source can be increased by using multiple sources at lower drive conditions to achieve the same excitation power as a single source driven at more harsh conditions such as higher current and voltage.

In a specific area of light source application is automobile headlamp. Semiconductor based light emitting diode (LED) headlight sources were fielded in 2004, the first solid-state sources. These featured high efficiency, reliability, and compactness, but the limited light output per device and brightness caused the optics and heat sinks to be still are quite large, and the elevated temperature requirements in auto applications were challenging. Color uniformity from the blue LED excited yellow phosphor needed managed with special reflector design. Single LED failure meant the entire headlamp needed to be scrapped, resulting in challenging costs for maintenance, repair, and warranty. Moreover, the LED components are based on spontaneous emission, and therefore are not conducive to high-speed modulation required for advanced applications such as 3D sensing (LiDAR), or optical communication (LiFi). The low luminance also creates challenges for spatially dynamic automotive lighting systems that utilize spatial modulators such as MEMS or liquid crystal devices. Semiconductor laser diode (LD) based headlights started production in 2014 based on laser pumped phosphor architectures, since direct emitting lasers such as R-G-B lasers are not safe to deploy onto the road and since R-G-B sources leave gaps in the spectrum that would leave common roadside targets such as yellow or orange with insufficient reflection back to the eye. Laser pumped phosphor are solid state light sources and therefore featured the same benefits of LEDs, but with higher brightness and range from more compact headlamp reflectors. Initially, these sources exhibited high costs, reduced reliability compared to LEDs, due to being newer technology. In some cases, the laser and phosphor were combined in a single unit, and in other cases, the blue laser light was delivered by fiber to a phosphor module to produce white. Special precautions were needed to ensure safe white light emission occurred with passive and active safety measures. Color uniformity from the blue laser excited yellow phosphor needed managed with special reflector design.

In some embodiments, the invention described herein can be applied to a fiber delivered headlight comprised of one or more gallium and nitrogen containing visible laser diode for emitting laser light that is efficiently coupled into a waveguide (such as an optical fiber) to deliver the laser emission to a remote phosphor member configured on the other end of the optical fiber. The laser emission serves to excite the phosphor member and generate a high brightness white light. In a headlight application, the phosphor member and white light generation occurs in a final headlight module, from where the light is collimated and shaped onto the road to achieve the desired light pattern.

This disclosure utilizes fiber delivery of visible laser light from a gallium and nitrogen containing laser diode to a remote phosphor member to generate a white light with high luminance, and has several key benefits over other approaches. One advantage lies in production of controllable light output or amount of light for low beam or high beam using modular design in a miniature headlight module footprint. Another advantage is to provide high luminance and long range of visibility. For example, based on recent driving speeds and safe stopping distances, a range of 800 meters to 1 km is possible from a 200 lumens on the road using a size<35 mm optic structure with light sources that are 1000 cd per mm². Using higher luminance light sources allows one to achieve longer-range visibility for the same optics size. Further advantage of the fiber-delivered white-light headlight is able to provide high contrast. It is important to minimize glare and maximize safety and visibility for drivers and others including oncoming traffic, pedestrians, animals, and drivers headed in the same direction traffic ahead. High luminance is required to produce sharp light gradients and the specific regulated light patterns for automotive lighting. Moreover, using a waveguide such as an optical fiber, extremely sharp light gradients and ultra-safe glare reduction can be generated by reshaping and projecting the decisive light cutoff that exists from core to cladding in the light emission profile.

Another advantage of the present invention is able to provide rich spectrum white color light. Laser pumped phosphors are broadband solid-state light sources and therefore featured the same benefits of LEDs, but with higher luminance. Direct emitting lasers such as R-G-B lasers are not safe to deploy onto the road since R-G-B sources leave gaps in the spectrum that would leave common roadside targets such as yellow or orange with insufficient reflection back to the eye. Also, because of the remote nature of the light sources, the headlight module can be mounted onto a pre-existing heat sink with adequate thermal mass that is located anywhere in the vehicle, eliminating the need for heat sink in the headlight.

One big advantage is small form factor of the light source and a low-cost solution for swiveling the light for glare mitigation and enhancing aerodynamic performance. For example, miniature optics <1 cm in diameter in a headlight module can be utilized to capture nearly 100% of the light from the fiber. The white light can be collimated and shaped with tiny diffusers or simple optical elements to produce the desired beam pattern on the road. it is desired to have extremely small optics sizes for styling of the vehicle. Using higher luminance light sources allows one to achieve smaller optics sizes for the same range of visibility. This headlight design allows one to integrate the headlight module into the grill, onto wheel cover, into seams between the hood and front bumper, etc. This headlight design features a headlight module that is extremely low mass and lightweight, and therefore minimized weight in the front of the car, contributing to safety, fuel economy, and speed/acceleration performance. For electric vehicles, this translates to increased vehicle range. Moreover, the decoupled fiber delivered architecture use pre-existing heat sink thermal mass already in vehicle, further minimizing the weight in the car. Furthermore, this headlight module is based on solid-state light source, and has long lifetime >10,000 hours. Redundancy and interchangeability are straightforward by simply replacing the fiber-delivered laser light source.

Because of the fiber configuration in the design of the fiber-delivered laser-based white light headlight module, reliability is maximized by positioning the laser-based light source away from the hot area near engine and other heat producing components. This allows the headlight module to operate at extremely high temperatures >100° C., while the laser module can operate in a cool spot with ample heat sinking. In a specific embodiment, the present invention utilizes thermally stable, military standard style, telcordia type packaging technology. The only elements exposed to the front of the car are the complexly passive headlight module, comprised tiny macro-optical elements. There is no laser directly deployed in the headlight module, only incoherent white light and a reflective phosphor architecture inside. Direct emitting lasers such as R-G-B lasers are not safe to deploy onto the road at high power and are not used in this design. It is safe and cost efficient to assemble this fiber-delivered white light source into the car while manufacturing the vehicle.

In LED-based headlights, if one high power LED element dies, the entire headlamp is typically scrapped. The fiber-delivered headlight design enables “plug and play” replacement of the light source, eliminating wasted action of completely scrapping headlights due to a failed component. The plug and play can occur without alignment, like replacing a battery, minimize warranty costs. This eliminates excessive replacement cost, customer wait times, dangerous driving conditions, and expensive loaner vehicles. Because of the ease of generating new light patterns, and the modular approach to lumen scaling, this fiber-delivered light source allows for changing lumens and beam pattern for any region without retooling for an entirely new headlamp. This convenient capability to change beam pattern can be achieved by changing tiny optics and or diffusers instead of retooling for new large reflectors. Moreover, the fiber-delivered white light source can be used in interior lights and daytime running lights (DRL), with transport or side emitting plastic optical fiber (POF).

Spatially dynamic beam shaping devices such as digital-light processing (DLP), liquid-crystal display (LCD), 1 or 2 MEMS or Galvo mirror systems, lightweight swivels, scanning fiber tips. Future spatially dynamic sources may require even brighter light, such as 5000-10000 lumens from the source, to produce high definition spatial light modulation on the road using MEMS or liquid crystal components. Such dynamic lighting systems are incredibly bulky and expensive when co-locating the light source, electronics, heat sink, optics, and light modulators, and secondary optics. Therefore, they require-fiber delivered high luminance white light to enable spatial light modulation in a compact and more cost-effective manner.

A additional advantage of combining the emission from multiple laser diode emitters is the potential for a more circular spot by rotating the first free space diverging elliptical laser beam by 90 degrees relative to the second free space diverging elliptical laser beam and overlapping the centered ellipses on the phosphor. Alternatively, a more circular spot can be achieved by rotating the first free space diverging elliptical laser beam by 180 degrees relative to the second free space diverging elliptical laser beam and off-centered overlapping the ellipses on the phosphor to increase spot diameter in slow axis diverging direction. In another configuration, more than 2 lasers are included and some combination of the above described beam shaping spot geometry shaping is achieved. A third and important advantage is that multiple color lasers in an emitting device can significantly improve color quality (CRI and CQS) by improving the fill of the spectra in the violet/blue and cyan region of the visible spectrum. For example, two or more blue excitation lasers with slightly detuned wavelengths (e.g. 5 nm, 10 nm, 15 nm, etc.) can be included to excite a yellow phosphor and create a larger blue spectrum.

As used herein, the term GaN substrate is associated with Group III-nitride based materials including GaN, InGaN, AlGaN, or other Group III containing alloys or compositions that are used as starting materials. Such starting materials include polar GaN substrates (i.e., substrate where the largest area surface is nominally an (h k 1) plane wherein h=k=0, and 1 is non-zero), non-polar GaN substrates (i.e., substrate material where the largest area surface is oriented at an angle ranging from about 80-100 degrees from the polar orientation described above towards an (h k l) plane wherein l=0, and at least one of h and k is non-zero) or semi-polar GaN substrates (i.e., substrate material where the largest area surface is oriented at an angle ranging from about +0.1 to 80 degrees or 110-179.9 degrees from the polar orientation described above towards an (h k l) plane wherein l=0, and at least one of h and k is non-zero). Of course, there can be other variations, modifications, and alternatives.

The laser diode device can be fabricated on a conventional orientation of a gallium and nitrogen containing film or substrate (e.g., GaN) such as the polar c-plane, on a nonpolar orientation such as the m-plane, or on a semipolar orientation such as the {30-31}, {20-21}, {30-32}, {11-22}, {10-11}, {30-3-1}, {20-2-1}, {30-3-2}, or offcuts of any of these polar, nonpolar, and semipolar planes within +/−10 degrees towards a c-plane, and/or +/−10 degrees towards an a-plane, and/or +/−10 degrees towards an m-plane. In some embodiments, a gallium and nitrogen containing laser diode laser diode comprises a gallium and nitrogen containing substrate. The substrate member may have a surface region on the polar {0001} plane (c-plane), nonpolar plane (m-plane, a-plane), and semipolar plain ({11-22}, {10-1-1}, {20-21}, {30-31}) or other planes of a gallium and nitrogen containing substrate. The laser device can be configured to emit a laser beam characterized by one or more wavelengths from about 390 nm to about 540 nm.

FIG. 3 is a simplified schematic diagram of a laser diode formed on a gallium and nitrogen containing substrate with the cavity aligned in a direction ended with cleaved or etched mirrors according to some embodiments of the present invention. In an example, the substrate surface 101 is a polar c-plane and the laser stripe region 110 is characterized by a cavity orientation substantially in an m-direction 10, which is substantially normal to an a-direction 20, but can be others such as cavity alignment substantially in the a-direction. The laser strip region 110 has a first end 107 and a second end 109 and is formed on an m-direction on a {0001} gallium and nitrogen containing substrate having a pair of cleaved or etched mirror structures, which face each other. In another example, the substrate surface 101 is a semipolar plane and the laser stripe region 110 is characterized by a cavity orientation substantially in a projection of a c-direction 10, which is substantially normal to an a-direction 20, but can be others such as cavity alignment substantially in the a-direction. The laser strip region 110 has a first end 107 and a second end 109 and is formed on an semipolar substrate such as a {40-41}, {30-31}, {20-21}, {40-4-1}, {30-3-1}, {20-2-1}, {20-21}, or an offcut of these planes within +/−5 degrees from the c-plane and a-plane gallium and nitrogen containing substrate. Optionally, the gallium nitride substrate member is a bulk GaN substrate characterized by having a nonpolar or semipolar crystalline surface region, but can be others. The bulk GaN substrate may have a surface dislocation density below 10⁵ cm⁻² or 10⁵ to 107 cm⁻². The nitride crystal or wafer may comprise Al_(x)In_(y)Ga_(1-x-y)N, where 0≤x, y, x+y≤1. In one specific embodiment, the nitride crystal comprises GaN. In some embodiments, the GaN substrate has threading dislocations, at a concentration between about 10⁵ cm⁻² and about 10⁸ cm⁻², in a direction that is substantially orthogonal or oblique with respect to the surface.

The exemplary laser diode devices in FIG. 3 have a pair of cleaved or etched mirror structures 109 and 107, which face each other. The first cleaved or etched facet 109 comprises a reflective coating and the second cleaved or etched facet 107 comprises no coating, an antireflective coating, or exposes gallium and nitrogen containing material. The first cleaved or etched facet 109 is substantially parallel with the second cleaved or etched facet 107. The first and second cleaved facets 109 and 107 are provided by a scribing and breaking process according to an embodiment or alternatively by etching techniques using etching technologies such as reactive ion etching (RIE), inductively coupled plasma etching (ICP), or chemical assisted ion beam etching (CAIBE), or other method. The reflective coating is selected from silicon dioxide, hafnia, and titania, tantalum pentoxide, zirconia, aluminum oxide, aluminum nitride, and aluminum oxynitride including combinations, and the like. Depending upon the design, the mirror surfaces can also comprise an anti-reflective coating.

In a specific embodiment, the method of facet formation includes subjecting the substrates to a laser for pattern formation. In a preferred embodiment, the pattern is configured for the formation of a pair of facets for a ridge laser. In a preferred embodiment, the pair of facets face each other and are in parallel alignment with each other. In a preferred embodiment, the method uses a UV (355 nm) laser to scribe the laser bars. In a specific embodiment, the laser is configured on a system, which allows for accurate scribe lines configured in a different patterns and profiles. In some embodiments, the laser scribing can be performed on the backside, front-side, or both depending upon the application. Of course, there can be other variations, modifications, and alternatives.

In a specific embodiment, the method uses backside laser scribing or the like. With backside laser scribing, the method preferably forms a continuous line laser scribe that is perpendicular to the laser bars on the backside of the GaN substrate. In a specific embodiment, the laser scribe is generally about 15-20 μm deep or other suitable depth. Preferably, backside scribing can be advantageous. That is, the laser scribe process does not depend on the pitch of the laser bars or other like pattern. Accordingly, backside laser scribing can lead to a higher density of laser bars on each substrate according to a preferred embodiment. In a specific embodiment, backside laser scribing, however, may lead to residue from the tape on the facets. In a specific embodiment, backside laser scribe often requires that the substrates face down on the tape. With front-side laser scribing, the backside of the substrate is in contact with the tape. Of course, there can be other variations, modifications, and alternatives.

It is well known that etch techniques such as chemical assisted ion beam etching (CAIBE), inductively coupled plasma (ICP) etching, or reactive ion etching (RIE) can result in smooth and vertical etched sidewall regions, which could serve as facets in etched facet laser diodes. In the etched facet process a masking layer is deposited and patterned on the surface of the wafer. The etch mask layer could be comprised of dielectrics such as silicon dioxide (SiO₂), silicon nitride (Si_(x)N_(y)), a combination thereof or other dielectric materials. Further, the mask layer could be comprised of metal layers such as Ni or Cr, but could be comprised of metal combination stacks or stacks comprising metal and dielectrics. In another approach, photoresist masks can be used either alone or in combination with dielectrics and/or metals. The etch mask layer is patterned using conventional photolithography and etch steps. The alignment lithography could be performed with a contact aligner or stepper aligner. Such lithographically defined mirrors provide a high level of control to the design engineer. After patterning of the photoresist mask on top of the etch mask is complete, the patterns in then transferred to the etch mask using a wet etch or dry etch technique. Finally, the facet pattern is then etched into the wafer using a dry etching technique selected from CABE, ICP, RIE and/or other techniques. The etched facet surfaces must be highly vertical of between about 87 and about 93 degrees or between about 89 and about 91 degrees from the surface plane of the wafer. The etched facet surface region must be very smooth with root mean square roughness values of less than about 50 nm, 20 nm, 5 nm, or 1 nm. Lastly, the etched must be substantially free from damage, which could act as nonradiative recombination centers and hence reduce the catastrophic optical mirror damage (COMD) threshold. CAIBE is known to provide very smooth and low damage sidewalls due to the chemical nature of the etch, while it can provide highly vertical etches due to the ability to tilt the wafer stage to compensate for any inherent angle in etch.

The laser stripe 110 is characterized by a length and width. The length ranges from about 50 μm to about 3000 μm, but is preferably between about 10 μm and about 400 μm, between about 400 μm and about 800 μm, or about 800 μm and about 1600 μm, but could be others. The stripe also has a width ranging from about 0.5 μm to about 50 μm, but is preferably between about 0.8 μm and about 2.5 μm for single lateral mode operation or between about 2.5 μm and about 50 μm for multi-lateral mode operation, but can be other dimensions. In a specific embodiment, the present device has a width ranging from about 0.5 μm to about 1.5 μm, a width ranging from about 1.5 μm to about 3.0 μm, a width ranging from about 3.0 μm to about 50 μm, and others. In a specific embodiment, the width is substantially constant in dimension, although there may be slight variations. The width and length are often formed using a masking and etching process, which are commonly used in the art.

The laser stripe region 110 is provided by an etching process selected from dry etching or wet etching. The device also has an overlying dielectric region, which exposes a p-type contact region. Overlying the contact region is a contact material, which may be metal or a conductive oxide or a combination thereof. The p-type electrical contact may be deposited by thermal evaporation, electron beam evaporation, electroplating, sputtering, or another suitable technique. Overlying the polished region of the substrate is a second contact material, which may be metal or a conductive oxide or a combination thereof and which comprises the n-type electrical contact. The n-type electrical contact may be deposited by thermal evaporation, electron beam evaporation, electroplating, sputtering, or another suitable technique.

In a specific embodiment, the laser device may emit red light with a center wavelength between 600 nm and 750 nm. Such a device may comprise layers of varying compositions of Al_(x)In_(y)Ga_(1-x-y)As_(z)P_(1-z), where x+y≤1 and z≤1. The red laser device comprises at least an n-type and p-type cladding layer, an n-type SCH of higher refractive index than the n-type cladding, a p-type SCH of higher refractive index than the p-type cladding and an active region where light is emitted. In a specific embodiment, the laser stripe is provided by an etching process selected from dry etching or wet etching. In a preferred embodiment, the etching process is dry, but can be others. The device also has an overlying dielectric region, which exposes the contact region. In a specific embodiment, the dielectric region is an oxide such as silicon dioxide, but can be others. Of course, there can be other variations, modifications, and alternatives. The laser stripe is characterized by a length and width. The length ranges from about 50 μm to about 3000 μm, but is preferably between 10 μm and 400 μm, between about 400 μm and 800 μm, or about 800 μm and 1600 μm, but could be others such as greater than 1600 μm. The stripe also has a width ranging from about 0.5 μm to about 80 μm, but is preferably between 0.8 μm and 2.5 μm for single lateral mode operation or between 2.5 μm and 60 μm for multi-lateral mode operation, but can be other dimensions. The laser strip region has a first end and a second end having a pair of cleaved or etched mirror structures, which face each other. The first facet comprises a reflective coating and the second facet comprises no coating, an antireflective coating, or exposes gallium and nitrogen containing material. The first facet is substantially parallel with the second cleaved or etched facet.

Given the high gallium and nitrogen containing substrate costs, difficulty in scaling up gallium and nitrogen containing substrate size, the inefficiencies inherent in the processing of small wafers, and potential supply limitations it becomes extremely desirable to maximize utilization of available gallium and nitrogen containing substrate and overlying epitaxial material. In the fabrication of lateral cavity laser diodes, it is typically the case that minimum die size is determined by device components such as the wire bonding pads or mechanical handling considerations, rather than by laser cavity widths. Minimizing die size is critical to reducing manufacturing costs as smaller die sizes allow a greater number of devices to be fabricated on a single wafer in a single processing run. The current invention is a method of maximizing the number of devices which can be fabricated from a given gallium and nitrogen containing substrate and overlying epitaxial material by spreading out the epitaxial material onto a carrier wafer via a die expansion process.

Similar to an edge emitting laser diode, a SLED is typically configured as an edge-emitting device wherein the high brightness, highly directional optical emission exits a waveguide directed outward from the side of the semiconductor chip. SLEDs are designed to have high single pass gain or amplification for the spontaneous emission generated along the waveguide. However, unlike laser diodes, they are designed to provide insufficient feedback to in the cavity to achieve the lasing condition where the gain equals the total losses in the waveguide cavity. In a typical example, at least one of the waveguide ends or facets is designed to provide very low reflectivity back into the waveguide. Several methods can be used to achieve reduced reflectivity on the waveguide end or facet. In one approach an optical coating is applied to at least one of the facets, wherein the optical coating is designed for low reflectivity such as less than 1%, less than 0.1%, less than 0.001%, or less than 0.0001% reflectivity. In another approach for reduced reflectivity the waveguide ends are designed to be tilted or angled with respect to the direction of light propagation such that the light that is reflected back into the chip does not constructively interfere with the light in the cavity to provide feedback. The tilt angle must be carefully designed around a null in the reflectivity versus angle relationship for optimum performance. The tilted or angled facet approach can be achieved in a number of ways including providing an etched facet that is designed with an optimized angle lateral angle with respect to the direction of light propagation. The angle of the tilt is pre-determined by the lithographically defined etched facet patter. Alternatively, the angled output could be achieved by curving and/or angling the waveguide with respect to a cleaved facet that forms on a pre-determined crystallographic plane in the semiconductor chip. Another approach to reduce the reflectivity is to provide a roughened or patterned surface on the facet to reduce the feedback to the cavity. The roughening could be achieved using chemical etching and/or a dry etching, or with an alternative technique. Of course, there may be other methods for reduced feedback to the cavity to form a SLED device. In many embodiments a number of techniques can be used in combination to reduce the facet reflectivity including using low reflectivity coatings in combination with angled or tilted output facets with respect to the light propagation.

In a specific embodiment on a nonpolar Ga-containing substrate, the device is characterized by a spontaneously emitted light is polarized in substantially perpendicular to the c-direction. In a preferred embodiment, the spontaneously emitted light is characterized by a polarization ratio of greater than 0.1 to about 1 perpendicular to the c-direction. In a preferred embodiment, the spontaneously emitted light characterized by a wavelength ranging from about 430 nanometers to about 470 nm to yield a blue emission, or about 500 nanometers to about 540 nanometers to yield a green emission, and others. For example, the spontaneously emitted light can be violet (e.g., 395 to 420 nanometers), blue (e.g., 420 to 470 nm); green (e.g., 500 to 540 nm), or others. In a preferred embodiment, the spontaneously emitted light is highly polarized and is characterized by a polarization ratio of greater than 0.4. In another specific embodiment on a semipolar {20-21} Ga-containing substrate, the device is also characterized by a spontaneously emitted light is polarized in substantially parallel to the a-direction or perpendicular to the cavity direction, which is oriented in the projection of the c-direction.

In a specific embodiment, the present invention provides an alternative device structure capable of emitting 501 nm and greater light in a ridge laser embodiment. The device is provided with a of the following epitaxially grown elements:

-   -   an n-GaN or n-AlGaN cladding layer with a thickness from 100 nm         to 3000 nm with Si doping level of 5×10¹⁷ cm⁻³ to 3×10¹⁸ cm⁻³;     -   an n-side SCH layer comprised of InGaN with molar fraction of         indium of between 2% and 15% and thickness from 20 nm to 250 nm;     -   a single quantum well or a multiple quantum well active region         comprised of at least two 2.0 nm to 8.5 nm InGaN quantum wells         separated by 1.5 nm and greater, and optionally up to about 12         nm, GaN or InGaN barriers;     -   a p-side SCH layer comprised of InGaN with molar a fraction of         indium of between 1% and 10% and a thickness from 15 nm to 250         nm or an upper GaN-guide layer;     -   an electron blocking layer comprised of AlGaN with molar         fraction of aluminum of between 0% and 22% and thickness from 5         nm to 20 nm and doped with Mg;     -   a p-GaN or p-AlGaN cladding layer with a thickness from 400 nm         to 1500 nm with Mg doping level of 2×10¹⁷ cm⁻³ to 2×10¹⁹ cm-3;         and     -   a p⁺⁺-GaN contact layer with a thickness from 20 nm to 40 nm         with Mg doping level of 1×10¹⁹ cm⁻³ to 1×10²¹ cm⁻³.

A gallium and nitrogen containing laser diode laser device may also include other structures, such as a surface ridge architecture, a buried heterostructure architecture, and/or a plurality of metal electrodes for selectively exciting the active region. For example, the active region may comprise first and second gallium and nitrogen containing cladding layers and an indium and gallium containing emitting layer positioned between the first and second cladding layers. A laser device may further include an n-type gallium and nitrogen containing material and an n-type cladding material overlying the n-type gallium and nitrogen containing material. In a specific embodiment, the device also has an overlying n-type gallium nitride layer, an active region, and an overlying p-type gallium nitride layer structured as a laser stripe region. Additionally, the device may also include an n-side separate confinement heterostructure (SCH), p-side guiding layer or SCH, p-AlGaN EBL, among other features. In a specific embodiment, the device also has a p++ type gallium nitride material to form a contact region. In a specific embodiment, the p++ type contact region has a suitable thickness and may range from about 10 nm 50 nm, or other thicknesses. In a specific embodiment, the doping level can be higher than the p-type cladding region and/or bulk region. In a specific embodiment, the p++ type region has doping concentration ranging from about 10¹⁹ to 10²¹ Mg/am³, and others. The p++ type region preferably causes tunneling between the semiconductor region and overlying metal contact region. In a specific embodiment, each of these regions is formed using at least an epitaxial deposition technique of metal organic chemical vapor deposition (MOCVD), molecular beam epitaxy (MBE), or other epitaxial growth techniques suitable for GaN growth. In a specific embodiment, the epitaxial layer is a high-quality epitaxial layer overlying the n-type gallium nitride layer. In some embodiments the high-quality layer is doped, for example, with Si or O to form n-type material, with a dopant concentration between about 10¹⁶ cm⁻³ and 10²⁰ cm⁻³.

FIG. 4 is a cross-sectional view of a laser device 200 according to some embodiments of the present disclosure. As shown, the laser device includes gallium nitride substrate 203, which has an underlying n-type metal back contact region 201. For example, the substrate 203 may be characterized by a semipolar or nonpolar orientation. The device also has an overlying n-type gallium nitride layer 205, an active region 207, and an overlying p-type gallium nitride layer structured as a laser stripe region 209. Each of these regions is formed using at least an epitaxial deposition technique of metal organic chemical vapor deposition (MOCVD), molecular beam epitaxy (MBE), or other epitaxial growth techniques suitable for GaN growth. The epitaxial layer is a high-quality epitaxial layer overlying the n-type gallium nitride layer. In some embodiments the high-quality layer is doped, for example, with Si or O to form n-type material, with a dopant concentration between about 10¹⁶ cm⁻³ and 10²⁰ cm⁻³.

An n-type Al_(u)In_(v)Ga_(1-u-v)N layer, where 0≤u, v, u+v≤1, is deposited on the substrate. The carrier concentration may lie in the range between about 10¹⁶ cm⁻³ and 10²⁰ cm⁻³. The deposition may be performed using metalorganic chemical vapor deposition (MOCVD) or molecular beam epitaxy (MBE).

For example, the bulk GaN substrate is placed on a susceptor in an MOCVD reactor. After closing, evacuating, and back-filling the reactor (or using a load lock configuration) to atmospheric pressure, the susceptor is heated to a temperature between about 1000 and about 1200 degrees Celsius in the presence of a nitrogen-containing gas. The susceptor is heated to approximately 900 to 1200 degrees Celsius under flowing ammonia. A flow of a gallium-containing metalorganic precursor, such as trimethylgallium (TMG) or triethylgallium (TEG) is initiated, in a carrier gas, at a total rate between approximately 1 and 50 standard cubic centimeters per minute (sccm). The carrier gas may comprise hydrogen, helium, nitrogen, or argon. The ratio of the flow rate of the group V precursor (ammonia) to that of the group III precursor (trimethylgallium, triethylgallium, trimethylindium, trimethylaluminum) during growth is between about 2000 and about 12000. A flow of disilane in a carrier gas, with a total flow rate of between about 0.1 sccm and 10 sccm, is initiated.

In one embodiment, the laser stripe region is p-type gallium nitride layer 209. The laser stripe is provided by a dry etching process, but wet etching can be used. The dry etching process is an inductively coupled process using chlorine bearing species or a reactive ion etching process using similar chemistries. The chlorine bearing species are commonly derived from chlorine gas or the like. The device also has an overlying dielectric region, which exposes a contact region 213. The dielectric region is an oxide such as silicon dioxide or silicon nitride, and a contact region is coupled to an overlying metal layer 215. The overlying metal layer is preferably a multilayered structure containing gold and platinum (Pt/Au), palladium and gold (Pd/Au), or nickel gold (Ni/Au), or a combination thereof. In some embodiments, barrier layers and more complex metal stacks are included.

Active region 207 preferably includes one to ten quantum-well regions or a double heterostructure region for light emission. Following deposition of the n-type Al_(u)In_(v)Ga_(1-u-v)N layer to achieve a desired thickness, an active layer is deposited. The quantum wells are preferably InGaN with GaN, AlGaN, InAlGaN, or InGaN barrier layers separating them. In other embodiments, the well layers and barrier layers comprise Al_(w)In_(x)Ga_(1-w-x)N and Al_(y)In_(z)Ga_(1-y-z)N, respectively, where 0≤w, x, y, z, w+x, y+z≤1, where w<u, y and/or x>v, z so that the bandgap of the well layer(s) is less than that of the barrier layer(s) and the n-type layer. The well layers and barrier layers each have a thickness between about 1 nm and about 20 nm. The composition and structure of the active layer are chosen to provide light emission at a preselected wavelength. The active layer may be left undoped (or unintentionally doped) or may be doped n-type or p-type.

The active region can also include an electron blocking region, and a separate confinement heterostructure. The electron-blocking layer may comprise Al_(s)In_(t)Ga_(1-s-t)N, where 0≤s, t, s+t≤1, with a higher bandgap than the active layer, and may be doped p-type. In one specific embodiment, the electron blocking layer includes AlGaN. In another embodiment, the electron blocking layer includes an AlGaN/GaN super-lattice structure, comprising alternating layers of AlGaN and GaN, each with a thickness between about 0.2 nm and about 5 nm.

As noted, the p-type gallium nitride or aluminum gallium nitride structure is deposited above the electron blocking layer and active layer(s). The p-type layer may be doped with Mg, to a level between about 10¹⁶ cm⁻³ and 10²² cm⁻³, with a thickness between about 5 nm and about 1000 nm. The outermost 1-50 nm of the p-type layer may be doped more heavily than the rest of the layer, so as to enable an improved electrical contact. The device also has an overlying dielectric region, for example, silicon dioxide, which exposes the contact region 213.

The metal contact is made of suitable material such as silver, gold, aluminum, nickel, platinum, rhodium, palladium, chromium, or the like. The contact may be deposited by thermal evaporation, electron beam evaporation, electroplating, sputtering, or another suitable technique. In a preferred embodiment, the electrical contact serves as a p-type electrode for the optical device. In another embodiment, the electrical contact serves as an n-type electrode for the optical device. The laser devices illustrated in FIG. 3 and FIG. 4 and described above are typically suitable for low-power applications.

In various embodiments, the present invention realizes high output power from a diode laser is by widening a portion of the laser cavity member from the single lateral mode regime of 1.0-3.0 μm to the multi-lateral mode range 5.0-20 μm. In some cases, laser diodes having cavities at a width of 50 μm or greater are employed.

The laser stripe length, or cavity length ranges from 100 to 3000 μm and employs growth and fabrication techniques such as those described in U.S. patent application Ser. No. 12/759,273, filed Apr. 13, 2010, which is incorporated by reference herein. As an example, laser diodes are fabricated on nonpolar or semipolar gallium containing substrates, where the internal electric fields are substantially eliminated or mitigated relative to polar c-plane oriented devices. It is to be appreciated that reduction in internal fields often enables more efficient radiative recombination. Further, the heavy hole mass is expected to be lighter on nonpolar and semipolar substrates, such that better gain properties from the lasers can be achieved.

Optionally, FIG. 4 illustrates an example cross-sectional diagram of a gallium and nitrogen based laser diode device. The epitaxial device structure is formed on top of the gallium and nitrogen containing substrate member 203. The substrate member may be n-type doped with O and/or Si doping. The epitaxial structures will contain n-side layers 205 such as an n-type buffer layer comprised of GaN, AlGaN, AlINGaN, or InGaN and n-type cladding layers comprised of GaN, AlGaN, or AlInGaN. The n-typed layers may have thickness in the range of 0.3 μm to about 3 μm or to about 5 μm and may be doped with an n-type carrier such as Si or O to concentrations between 1×10¹⁶ cm⁻³ to 1×10¹⁹ cm⁻³. Overlying the n-type layers is the active region and waveguide layers 207. This region could contain an n-side waveguide layer or separate confinement heterostructure (SCH) such as InGaN to help with optical guiding of the mode. The InGaN layer be comprised of 1 to 15% molar fraction of InN with a thickness ranging from about 30 nm to about 250 nm and may be doped with an n-type species such as Si. Overlying the SCH layer is the light emitting regions which could be comprised of a double heterostructure or a quantum well active region. A quantum well active region could be comprised of 1 to 10 quantum wells ranging in thickness from 1 nm to 20 nm comprised of InGaN. Barrier layers comprised of GaN, InGaN, or AlGaN separate the quantum well light emitting layers. The barriers range in thickness from 1 nm to about 25 nm. Overlying the light emitting layers are optionally an AlGaN or InAlGaN electron blocking layer with 5% to about 35% AlN and optionally doped with a p-type species such as Mg. Also optional is a p-side waveguide layer or SCH such as InGaN to help with optical guiding of the mode. The InGaN layer be comprised of 1 to 15% molar fraction of InN with a thickness ranging from 30 nm to about 250 nm and may be doped with an p-type species such as Mg. Overlying the active region and optional electron blocking layer and p-side waveguide layers is a p-cladding region and a p++ contact layer. The p-type cladding region is comprised of GaN, AlGaN, AlINGaN, or a combination thereof. The thickness of the p-type cladding layers is in the range of 0.3 μm to about 2 μm and is doped with Mg to a concentration of between 1×10¹⁶ cm⁻³ to 1×10¹⁹ cm⁻³. A ridge 211 is formed in the p-cladding region for lateral confinement in the waveguide using an etching process selected from a dry etching or a wet etching process. A dielectric material 213 such as silicon dioxide or silicon nitride or deposited on the surface region of the device and an opening is created on top of the ridge to expose a portion of the p++ GaN layer. A p-contact 215 is deposited on the top of the device to contact the exposed p++ contact region. The p-type contact may be comprised of a metal stack containing a of Au, Pd, Pt, Ni, Ti, or Ag and may be deposited with electron beam deposition, sputter deposition, or thermal evaporation. A n-contact 201 is formed to the bottom of the substrate member. The n-type contact may be comprised of a metal stack containing Au, Al, Pd, Pt, Ni, Ti, or Ag and may be deposited with electron beam deposition, sputter deposition, or thermal evaporation.

In multiple embodiments according to the present invention, the device layers comprise a super-luminescent light emitting diode or SLED. In all applicable embodiments a SLED device can be interchanged with or combined with laser diode devices according to the methods and architectures described in this invention. A SLED is in many ways similar to an edge emitting laser diode; however the emitting facet of the device is designed so as to have a very low reflectivity. A SLED is similar to a laser diode as it is based on an electrically driven junction that when injected with current becomes optically active and generates amplified spontaneous emission (ASE) and gain over a wide range of wavelengths. When the optical output becomes dominated by ASE there is a knee in the light output versus current (LI) characteristic wherein the unit of light output becomes drastically larger per unit of injected current. This knee in the LI curve resembles the threshold of a laser diode, but is much softer. A SLED would have a layer structure engineered to have a light emitting layer or layers clad above and below with material of lower optical index such that a laterally guided optical mode can be formed. The SLED would also be fabricated with features providing lateral optical confinement. These lateral confinement features may consist of an etched ridge, with air, vacuum, metal or dielectric material surrounding the ridge and providing a low optical-index cladding. The lateral confinement feature may also be provided by shaping the electrical contacts such that injected current is confined to a finite region in the device. In such a “gain guided” structure, dispersion in the optical index of the light emitting layer with injected carrier density provides the optical-index contrast needed to provide lateral confinement of the optical mode.

In an embodiment, the LD or SLED device is characterized by a ridge with non-uniform width. The ridge is comprised by a first section of uniform width and a second section of varying width. The first section has a length between 100 and 500 μm long, though it may be longer. The first section has a width of between 1 and 2.5 μm, with a width preferably between 1 and 1.5 μm. The second section of the ridge has a first end and a second end. The first end connects with the first section of the ridge and has the same width as the first section of the ridge. The second end of the second section of the ridge is wider than the first section of the ridge, with a width between 5 and 50 μm and more preferably with a width between 15 and 35 μm. The second section of the ridge waveguide varies in width between its first and second end smoothly. In some embodiments the second derivative of the ridge width versus length is zero such that the taper of the ridge is linear. In some embodiments, the second derivative is chosen to be positive or negative. In general, the rate of width increase is chosen such that the ridge does not expand in width significantly faster than the optical mode. In specific embodiments, the electrically injected area is patterned such that only a part of the tapered portion of the waveguide is electrically injected.

In an embodiment, multiple laser dice emitting at different wavelengths are transferred to the same carrier wafer in close proximity to one another; preferably within one millimeter of each other, more preferably within about 200 micrometers of each other and most preferably within about 50 μm of each other. The laser die wavelengths are chosen to be separated in wavelength by at least twice the full width at half maximum of their spectra. For example, three dice, emitting at 440 nm, 450 nm and 460 nm, respectively, are transferred to a single carrier chip with a separation between die of less than 50 μm and die widths of less than 50 μm such that the total lateral separation, center to center, of the laser light emitted by the die is less than 200 μm. The closeness of the laser die allows for their emission to be easily coupled into the same optical train or fiber optic waveguide or projected in the far field into overlapping spots. In a sense, the lasers can be operated effectively as a single laser light source.

Such a configuration offers an advantage in that each individual laser light source could be operated independently to convey information using for example frequency and phase modulation of an RF signal superimposed on DC offset. The time-averaged proportion of light from the different sources could be adjusted by adjusting the DC offset of each signal. At a receiver, the signals from the individual laser sources would be demultiplexed by use of notch filters over individual photodetectors that filter out both the phosphor derived component of the white light spectra as well as the pump light from all but one of the laser sources. Such a configuration would offer an advantage over an LED based visible light communication (VLC) source in that bandwidth would scale easily with the number of laser emitters. Of course, a similar embodiment with similar advantages could be constructed from SLED emitters.

After the laser diode chip fabrication as described above, the laser diode can be mounted to a submount. In some examples the submount is comprised of AlN, SiC, BeO, diamond, or other materials such as metals, ceramics, or composites. Alternatively, the submount can be an intermediate submount intended to be mounted to the common support member wherein the phosphor material is attached. The submount member may be characterized by a width, length, and thickness. In an example wherein the submount is the common support member for the phosphor and the laser diode chip the submount would have a width and length ranging in dimension from about 0.5 mm to about 5 mm or to about 15 mm and a thickness ranging from about 150 μm to about 2 mm. In the example wherein the submount is an intermediate submount between the laser diode chip and the common support member it could be characterized by width and length ranging in dimension from about 0.5 mm to about 5 mm and the thickness may range from about 50 μm to about 500 μm. The laser diode is attached to the submount using a bonding process, a soldering process, a gluing process, or a combination thereof. In one embodiment the submount is electrically isolating and has metal bond pads deposited on top. The laser chip is mounted to at least one of those metal pads. The laser chip can be mounted in a p-side down or a p-side up configuration. After bonding the laser chip, wire bonds are formed from the chip to the submount such that the final chip on submount (CoS) is completed and ready for integration.

A schematic diagram illustrating a CoS based on a conventional laser diode formed on gallium and nitrogen containing substrate technology according to this present invention is shown in FIG. 5. The CoS is comprised of submount material 301 configured to act as an intermediate material between a laser diode chip 302 and a final mounting surface. The submount is configured with electrodes 303 and 305 that may be formed with deposited metal layers such as Au. In one example, Ti/Pt/Au is used for the electrodes. Wirebonds 304 are configured to couple the electrical power from the electrodes 303 and 305 on the submount to the laser diode chip to generate a laser beam output 306 from the laser diode. The electrodes 303 and 305 are configured for an electrical connection to an external power source such as a laser driver, a current source, or a voltage source. Wirebonds 304 can be formed on the electrodes to couple electrical power to the laser diode device and activate the laser.

In another embodiment, the gallium and nitrogen containing laser diode fabrication includes an epitaxial release step to lift off the epitaxially grown gallium and nitrogen layers and prepare them for transferring to a carrier wafer which could comprise the submount after laser fabrication. The transfer step requires precise placement of the epitaxial layers on the carrier wafer to enable subsequent processing of the epitaxial layers into laser diode devices. The attachment process to the carrier wafer could include a wafer bonding step with a bond interface comprised of metal-metal, semiconductor-semiconductor, glass-glass, dielectric-dielectric, or a combination thereof.

In this embodiment, gallium and nitrogen containing epitaxial layers are grown on a bulk gallium and nitrogen containing substrate. The epitaxial layer stack comprises at least a sacrificial release layer and the laser diode device layers overlying the release layers. Following the growth of the epitaxial layers on the bulk gallium and nitrogen containing substrate, the semiconductor device layers are separated from the substrate by a selective wet etching process such as a PEC etch configured to selectively remove the sacrificial layers and enable release of the device layers to a carrier wafer. In one embodiment, a bonding material is deposited on the surface overlying the semiconductor device layers. A bonding material is also deposited either as a blanket coating or patterned on the carrier wafer. Standard lithographic processes are used to selectively mask the semiconductor device layers. The wafer is then subjected to an etch process such as dry etch or wet etch processes to define via structures that expose the sacrificial layers on the sidewall of the mesa structure. As used herein, the term mesa region or mesa is used to describe the patterned epitaxial material on the gallium and nitrogen containing substrate and prepared for transferring to the carrier wafer. The mesa region can be any shape or form including a rectangular shape, a square shape, a triangular shape, a circular shape, an elliptical shape, a polyhedron shape, or other shape. The term mesa shall not limit the scope of the present invention.

Following the definition of the mesa, a selective etch process is performed to fully or partially remove the sacrificial layers while leaving the semiconductor device layers intact. The resulting structure comprises undercut mesas comprised of epitaxial device layers. The undercut mesas correspond to dice from which semiconductor devices will be formed on. In some embodiments a protective passivation layer can be employed on the sidewall of the mesa regions to prevent the device layers from being exposed to the selective etch when the etch selectivity is not perfect. In other embodiments a protective passivation is not needed because the device layers are not sensitive to the selective etch or measures are taken to prevent etching of sensitive layers such as shorting the anode and cathode. The undercut mesas corresponding to device dice are then transferred to the carrier wafer using a bonding technique wherein the bonding material overlying the semiconductor device layers is joined with the bonding material on the carrier wafer. The resulting structure is a carrier wafer comprising gallium and nitrogen containing epitaxial device layers overlying the bonding region.

In a preferred embodiment PEC etching is deployed as the selective etch to remove the sacrificial layers. PEC is a photo-assisted wet etch technique that can be used to etch GaN and its alloys. The process involves an above-band-gap excitation source and an electrochemical cell formed by the semiconductor and the electrolyte solution. In this case, the exposed (Al,In,Ga)N material surface acts as the anode, while a metal pad deposited on the semiconductor acts as the cathode. The above-band-gap light source generates electron-hole pairs in the semiconductor. Electrons are extracted from the semiconductor via the cathode while holes diffuse to the surface of material to form an oxide. Since the diffusion of holes to the surface requires the band bending at the surface to favor a collection of holes, PEC etching typically works only for n-type material although some methods have been developed for etching p-type material. The oxide is then dissolved by the electrolyte resulting in wet etching of the semiconductor. Different types of electrolyte including HCl, KOH, and HNO₃ have been shown to be effective in PEC etching of GaN and its alloys. The etch selectivity and etch rate can be optimized by selecting a favorable electrolyte. It is also possible to generate an external bias between the semiconductor and the cathode to assist with the PEC etching process.

In a preferred embodiment, a semiconductor device epitaxy material with the underlying sacrificial region is fabricated into a dense array of mesas on the gallium and nitrogen containing bulk substrate with the overlying semiconductor device layers. The mesas are formed using a patterning and a wet or dry etching process wherein the patterning comprises a lithography step to define the size and pitch of the mesa regions. Dry etching techniques such as reactive ion etching, inductively coupled plasma etching, or chemical assisted ion beam etching are candidate methods. Alternatively, a wet etch can be used. The etch is configured to terminate at or below a sacrificial region below the device layers. This is followed by a selective etch process such as PEC to fully or partially etch the exposed sacrificial region such that the mesas are undercut. This undercut mesa pattern pitch will be referred to as the ‘first pitch’. The first pitch is often a design width that is suitable for fabricating each of the epitaxial regions on the substrate, while not large enough for the desired completed semiconductor device design, which often desire larger non-active regions or regions for contacts and the like. For example, these mesas would have a first pitch ranging from about 5 μm to about 500 μm or to about 5000 μm. Each of these mesas is a ‘die’.

In a preferred embodiment, these dice are transferred to a carrier wafer at a second pitch using a selective bonding process such that the second pitch on the carrier wafer is greater than the first pitch on the gallium and nitrogen containing substrate. In this embodiment the dice are on an expanded pitch for so called “die expansion”. In an example, the second pitch is configured with the dice to allow each die with a portion of the carrier wafer to be a semiconductor device, including contacts and other components. For example, the second pitch would be about 50 μm to about 1000 μm or to about 5000 μm, but could be as large at about 3-10 mm or greater in the case where a large semiconductor device chip is required for the application. The larger second pitch could enable easier mechanical handling without the expense of the costly gallium and nitrogen containing substrate and epitaxial material, allow the real estate for additional features to be added to the semiconductor device chip such as bond pads that do not require the costly gallium and nitrogen containing substrate and epitaxial material, and/or allow a smaller gallium and nitrogen containing epitaxial wafer containing epitaxial layers to populate a much larger carrier wafer for subsequent processing for reduced processing cost. For example, a 4 to 1 die expansion ratio would reduce the density of the gallium and nitrogen containing material by a factor of 4, and hence populate an area on the carrier wafer 4 times larger than the gallium and nitrogen containing substrate. This would be equivalent to turning a 2″ gallium and nitrogen substrate into a 4″ carrier wafer. In particular, the present invention increases utilization of substrate wafers and epitaxy material through a selective area bonding process to transfer individual die of epitaxy material to a carrier wafer in such a way that the die pitch is increased on the carrier wafer relative to the original epitaxy wafer. The arrangement of epitaxy material allows device components which do not require the presence of the expensive gallium and nitrogen containing substrate and overlying epitaxy material often fabricated on a gallium and nitrogen containing substrate to be fabricated on the lower cost carrier wafer, allowing for more efficient utilization of the gallium and nitrogen containing substrate and overlying epitaxy material.

FIG. 6 is a schematic representation of the die expansion process with selective area bonding according to the present invention. A device wafer is prepared for bonding in accordance with an embodiment of this invention. The device wafer consists of a substrate 606, buffer layers 603, a fully removed sacrificial layer 609, device layers 602, bonding media 601, cathode metal 605, and an anchor material 604. The sacrificial layer 609 is removed in the PEC etch with the anchor material 604 is retained. The mesa regions formed in the gallium and nitrogen containing epitaxial wafer form dice of epitaxial material and release layers defined through processing. Individual epitaxial material die are formed at first pitch. A carrier wafer is prepared consisting of the carrier wafer substrate 607 and bond pads 608 at second pitch. The substrate 606 is aligned to the carrier wafer 607 such that a subset of the mesa on the gallium and nitrogen containing substrate 606 with a first pitch aligns with a subset of bond pads 608 on the carrier wafer 607 at a second pitch. Since the first pitch is greater than the second pitch and the mesas will comprise device die, the basis for die expansion is established. The bonding process is carried out and upon separation of the substrate from the carrier wafer 607 the subset of mesas on the substrate 606 are selectively transferred to the carrier wafer 607. The process is then repeated with a second set of mesas and bond pads 608 on the carrier wafer 607 until the carrier wafer 607 is populated fully by epitaxial mesas. The gallium and nitrogen containing epitaxy substrate 201 can now optionally be prepared for reuse.

In the example depicted in FIG. 6, one quarter of the epitaxial dice on the epitaxy wafer 606 are transferred in this first selective bond step, leaving three quarters on the epitaxy wafer 606. The selective area bonding step is then repeated to transfer the second quarter, third quarter, and fourth quarter of the epitaxial die to the patterned carrier wafer 607. This selective area bond may be repeated any number of times and is not limited to the four steps depicted in FIG. 6. The result is an array of epitaxial die on the carrier wafer 607 with a wider die pitch than the original die pitch on the epitaxy wafer 606. The die pitch on the epitaxial wafer 606 will be referred to as pitch 1, and the die pitch on the carrier wafer 607 will be referred to as pitch 2, where pitch 2 is greater than pitch 1.

In one embodiment the bonding between the carrier wafer and the gallium and nitrogen containing substrate with epitaxial layers is performed between bonding layers that have been applied to the carrier and the gallium and nitrogen containing substrate with epitaxial layers. The bonding layers can be a variety of bonding pairs including metal-metal, oxide-oxide, soldering alloys, photoresists, polymers, wax, etc. Only epitaxial dice which are in contact with a bond bad 608 on the carrier wafer 607 will bond. Sub-micron alignment tolerances are possible on commercial die bonders. The epitaxy wafer 606 is then pulled away, breaking the epitaxy material at a weakened epitaxial release layer 609 such that the desired epitaxial layers remain on the carrier wafer 607. Herein, a ‘selective area bonding step’ is defined as a single iteration of this process.

In one embodiment, the carrier wafer 607 is patterned in such a way that only selected mesas come in contact with the metallic bond pads 608 on the carrier wafer 607. When the epitaxy substrate 606 is pulled away the bonded mesas break off at the weakened sacrificial region, while the un-bonded mesas remain attached to the epitaxy substrate 606. This selective area bonding process can then be repeated to transfer the remaining mesas in the desired configuration. This process can be repeated through any number of iterations and is not limited to the two iterations depicted in FIG. 6. The carrier wafer can be of any size, including but not limited to about 2 inch, 3 inch, 4 inch, 6 inch, 8 inch, and 12 inch. After all desired mesas have been transferred, a second bandgap selective PEC etching can be optionally used to remove any remaining sacrificial region material to yield smooth surfaces. At this point standard semiconductor device processes can be carried out on the carrier wafer. Another embodiment of the invention incorporates the fabrication of device components on the dense epitaxy wafers before the selective area bonding steps.

In an example, the present invention provides a method for increasing the number of gallium and nitrogen containing semiconductor devices which can be fabricated from a given epitaxial surface area; where the gallium and nitrogen containing epitaxial layers overlay gallium and nitrogen containing substrates. The gallium and nitrogen containing epitaxial material is patterned into die with a first die pitch; the die from the gallium and nitrogen containing epitaxial material with a first pitch is transferred to a carrier wafer to form a second die pitch on the carrier wafer; the second die pitch is larger than the first die pitch.

In an example, each epitaxial device die is an etched mesa with a pitch of between about 1 μm and about 100 μm wide or between about 100 μm and about 500 μm wide or between about 500 μm and about 3000 μm wide and between about 100 and about 3000 μm long. In an example, the second die pitch on the carrier wafer is between about 100 μm and about 200 μm or between about 200 μm and about 1000 μm or between about 1000 μm and about 3000 μm. In an example, the second die pitch on the carrier wafer is between about 2 times and about 50 times larger than the die pitch on the epitaxy wafer. In an example, semiconductor LED devices, laser devices, or electronic devices are fabricated on the carrier wafer after epitaxial transfer. In an example, the semiconductor devices contain GaN, AlN, InN, InGaN, AlGaN, InAlN, and/or InAlGaN. In an example, the gallium and nitrogen containing material are grown on a polar, nonpolar, or semipolar plane. In an example, one or multiple semiconductor devices are fabricated on each die of epitaxial material. In an example, device components which do not require epitaxy material are placed in the space between epitaxy die.

In one embodiment, device dice are transferred to a carrier wafer such that the distance between die is expanded in both the transverse as well as lateral directions. This can be achieved by spacing bond pads on the carrier wafer with larger pitches than the spacing of device die on the substrate.

In another embodiment of the invention device dice from a plurality of epitaxial wafers are transferred to the carrier wafer such that each design width on the carrier wafer contains dice from a plurality of epitaxial wafers. When transferring dice at close spacing from multiple epitaxial wafers, it is important for the un-transferred dice on the epitaxial wafer to not inadvertently contact and bond to die already transferred to the carrier wafer. To achieve this, epitaxial dice from a first epitaxial wafer are transferred to a carrier wafer using the methods described above. A second set of bond pads are then deposited on the carrier wafer and are made with a thickness such that the bonding surface of the second pads is higher than the top surface of the first set of transferred die. This is done to provide adequate clearance for bonding of the dice from the second epitaxial wafer. A second epitaxial wafer transfers a second set of dice to the carrier wafer. Finally, the semiconductor devices are fabricated, and passivation layers are deposited followed by electrical contact layers that allow each die to be individually driven. The dice transferred from the first and second substrates are spaced at a pitch which is smaller than the second pitch of the carrier wafer. This process can be extended to transfer of dice from any number of epitaxial substrates, and to transfer of any number of devices per dice from each epitaxial substrate.

A schematic diagram illustrating a CoS based on lifted off and transferred epitaxial gallium and nitrogen containing layers according to this present invention is shown in FIG. 7. The CoS is comprised of submount material 901 configured from the carrier wafer with the transferred epitaxial material with a laser diode configured within the epitaxy 902. Electrodes 903 and 904 are electrically coupled to the n-side and the p-side of the laser diode device and configured to transmit power from an external source to the laser diode to generate a laser beam output 905 from the laser diode. The electrodes are configured for an electrical connection to an external power source such as a laser driver, a current source, or a voltage source. Wirebonds can be formed on the electrodes to couple the power to the laser diode device. This integrated CoS device with transferred epitaxial material offers advantages over the conventional configuration such as size, cost, and performance due to the low thermal impedance.

Further process and device description for this embodiment describing laser diodes formed in gallium and nitrogen containing epitaxial layers that have been transferred from the native gallium and nitrogen containing substrates are described in U.S. patent application Ser. No. 14/312,427 and U.S. Patent Publication No. 2015/0140710, which are incorporated by reference herein. As an example, this technology of GaN transfer can enable lower cost, higher performance, and a more highly manufacturable process flow.

Phosphor selection is a key consideration within the laser based integrated white light source. The phosphor must be able to withstand the extreme optical intensity and associated heating induced by the laser excitation spot without severe degradation. Important characteristics to consider for phosphor selection include:

-   -   A high conversion efficiency of optical excitation power to         white light lumens. In the example of a blue laser diode         exciting a yellow phosphor, a conversion efficiency of over 150         lumens per optical watt, or over 200 lumens per optical watt, or         over 300 lumens per optical watt is desired.     -   A high optical damage threshold capable of withstanding 1-20 W         of laser power in a spot comprising a diameter of 1 mm, 500 μm,         200 μm, 100 μm, or even 50 μm.     -   High thermal damage threshold capable of withstanding         temperatures of over 150° C., over 200° C., or over 300° C.         without decomposition.     -   A low thermal quenching characteristic such that the phosphor         remains efficient as it reaches temperatures of over 150° C.,         200° C., or 250° C.     -   A high thermal conductivity to dissipate the heat and regulate         the temperature. Thermal conductivities of greater than 3 W/m-K,         greater than 5 W/m-K, greater than 10 W/m-K, and even greater         than 15 W/m-K are desirable.     -   A proper phosphor emission color for the application.     -   A suitable porosity characteristic that leads to the desired         scattering of the coherent excitation without unacceptable         reduction in thermal conductivity or optical efficiency.     -   A proper form factor for the application. Such form factors         include, but are not limited to blocks, plates, disks, spheres,         cylinders, rods, or a similar geometrical element. Proper choice         will be dependent on whether phosphor is operated in         transmissive or reflective mode and on the absorption length of         the excitation light in the phosphor.     -   A surface condition optimized for the application. In an         example, the phosphor surfaces can be intentionally roughened         for improved light extraction.

In a preferred embodiment, a blue laser diode operating in the 420 nm to 480 nm wavelength range would be combined with a phosphor material providing a yellowish emission in the 560 nm to 580 nm range such that when mixed with the blue emission of the laser diode a white light is produced. For example, to meet a white color point on the black body line the energy of the combined spectrum may be comprised of about 30% from the blue laser emission and about 70% from the yellow phosphor emission. In other embodiments phosphors with red, green, yellow, and even blue emission can be used in combination with the laser diode excitation sources in the violet, ultra-violet, or blue wavelength range to produce a white light with color mixing. Although such white light systems may be more complicated due to the use of more than one phosphor member, advantages such as improved color rendering could be achieved.

In an example, the light emitted from the laser diodes is partially converted by the phosphor element. In an example, the partially converted light emitted generated in the phosphor element results in a color point, which is white in appearance. In an example, the color point of the white light is located on the Planckian blackbody locus of points. In an example, the color point of the white light is located within du′v′ of less than 0.010 of the Planckian blackbody locus of points. In an example, the color point of the white light is preferably located within du′v′ of less than 0.03 of the Planckian blackbody locus of points.

The phosphor material can be operated in a transmissive mode, a reflective mode, or a combination of a transmissive mode and reflective mode, or other modes. The phosphor material is characterized by a conversion efficiency, a resistance to thermal damage, a resistance to optical damage, a thermal quenching characteristic, a porosity to scatter excitation light, and a thermal conductivity. In a preferred embodiment the phosphor material is comprised of a yellow emitting YAG material doped with Ce with a conversion efficiency of greater than 100 lumens per optical watt, greater than 200 lumens per optical watt, or greater than 300 lumens per optical watt, and can be a polycrystalline ceramic material or a single crystal material.

In some embodiments of the present invention, the environment of the phosphor can be independently tailored to result in high efficiency with little or no added cost. Phosphor optimization for laser diode excitation can include high transparency, scattering or non-scattering characteristics, and use of ceramic phosphor plates. Decreased temperature sensitivity can be determined by doping levels. A reflector can be added to the backside of a ceramic phosphor, reducing loss. The phosphor can be shaped to increase in-coupling, increase out-coupling, and/or reduce back reflections. Surface roughening is a well-known means to increase extraction of light from a solid material. Coatings, mirrors, or filters can be added to the phosphors to reduce the amount of light exiting the non-primary emission surfaces, to promote more efficient light exit through the primary emission surface, and to promote more efficient in-coupling of the laser excitation light. Of course, there can be additional variations, modifications, and alternatives.

In some embodiments, certain types of phosphors will be best suited in this demanding application with a laser excitation source. As an example, ceramic yttrium aluminum garnets (YAG) doped with Ce³⁺ ions, or YAG based phosphors can be ideal candidates. They are doped with species such as Ce to achieve the proper emission color and are often comprised of a porosity characteristic to scatter the excitation source light, and nicely break up the coherence in laser excitation. As a result of its cubic crystal structure the YAG:Ce can be prepared as a highly transparent single crystal as well as a polycrystalline bulk material. The degree of transparency and the luminescence are depending on the stoichiometric composition, the content of dopant, and entire processing and sintering route. The transparency and degree of scattering centers can be optimized for a homogenous mixture of blue and yellow light. The YAG:Ce can be configured to emit a green emission. In some embodiments the YAG can be doped with Eu to emit a red emission.

In a preferred embodiment according to this invention, the white light source is configured with a ceramic polycrystalline YAG:Ce phosphors comprising an optical conversion efficiency of greater than 100 lumens per optical excitation watt, of greater than 200 lumens per optical excitation watt, or even greater than 300 lumens per optical excitation watt. Additionally, the ceramic YAG:Ce phosphors is characterized by a temperature quenching characteristics above 150° C., above 200° C., or above 250° C. and a high thermal conductivity of 5-10 W/m-K to effectively dissipate heat to a heat sink member and keep the phosphor at an operable temperature.

In another preferred embodiment according to this invention, the white light source is configured with a single crystal phosphor (SCP) such as YAG:Ce. In one example the Ce:Y₃Al₅O₁₂ SCP can be grown by the Czochralski technique. In this embodiment according the present invention the SCP based on YAG:Ce is characterized by an optical conversion efficiency of greater than 100 lumens per optical excitation watt, of greater than 200 lumens per optical excitation watt, or even greater than 300 lumens per optical excitation watt. Additionally, the single crystal YAG:Ce phosphors is characterized by a temperature quenching characteristics above 150° C., above 200° C., or above 300° C. and a high thermal conductivity of 8-20 W/m-K to effectively dissipate heat to a heat sink member and keep the phosphor at an operable temperature. In addition to the high thermal conductivity, high thermal quenching threshold, and high conversion efficiency, the ability to shape the phosphors into tiny forms that can act as ideal “point” sources when excited with a laser is an attractive feature.

In some embodiments the YAG:Ce can be configured to emit a yellow emission. In alternative or the same embodiments a YAG:Ce can be configured to emit a green emission. In yet alternative or the same embodiments the YAG can be doped with Eu to emit a red emission. In some embodiments a LuAG is configured for emission. In alternative embodiments, silicon nitrides or aluminum-oxi-nitrides can be used as the crystal host materials for red, green, yellow, or blue emissions.

In an alternative embodiment, a powdered single crystal or ceramic phosphor such as a yellow phosphor or green phosphor is included. The powdered phosphor can be dispensed on a transparent member for a transmissive mode operation or on a solid member with a reflective layer on the back surface of the phosphor or between the phosphor and the solid member to operate in a reflective mode. The phosphor powder may be held together in a solid structure using a binder material wherein the binder material is preferable in inorganic material with a high optical damage threshold and a favorable thermal conductivity. The phosphor power may be comprised of a colored phosphor and configured to emit a white light when excited by and combined with the blue laser beam or excited by a violet laser beam. The powdered phosphors could be comprised of YAG, LuAG, or other types of phosphors.

In one embodiment of the present invention the phosphor material contains a yttrium aluminum garnet host material and a rare earth doping element, and others. In an example, the wavelength conversion element is a phosphor which contains a rare earth doping element, selected from a of Ce, Nd, Er, Yb, Ho, Tm, Dy and Sm, combinations thereof, and the like. In an example, the phosphor material is a high-density phosphor element. In an example, the high-density phosphor element has a density greater than 90% of pure host crystal. Cerium (III)-doped YAG (YAG:Ce³⁺, or Y₃Al₅O₁₂:Ce³⁺) can be used wherein the phosphor absorbs the light from the blue laser diode and emits in a broad range from greenish to reddish, with most of output in yellow. This yellow emission combined with the remaining blue emission gives the “white” light, which can be adjusted to color temperature as warm (yellowish) or cold (bluish) white. The yellow emission of the Ce³⁺:YAG can be tuned by substituting the cerium with other rare earth elements such as terbium and gadolinium and can even be further adjusted by substituting some or all of the aluminum in the YAG with gallium.

In alternative examples, various phosphors can be applied to this invention, which include, but are not limited to organic dyes, conjugated polymers, semiconductors such as AlInGaP or InGaN, yttrium aluminum garnets (YAGs) doped with Ce³⁺ ions (Y_(1-a)Gd_(a))₃(Al_(1-b)Ga_(b))₅O₁₂:Ce³⁺, SrGa₂S₄:Eu²⁺, SrS:Eu²⁺, terbium aluminum based garnets (TAGs) (Tb₃Al₅O₅), colloidal quantum dot thin films containing CdTe, ZnS, ZnSe, ZnTe, CdSe, or CdTe.

In further alternative examples, some rare-earth doped SiAlONs can serve as phosphors. Europium(II)-doped β-SiAlON absorbs in ultraviolet and visible light spectrum and emits intense broadband visible emission. Its luminance and color does not change significantly with temperature, due to the temperature-stable crystal structure. In an alternative example, green and yellow SiAlON phosphor and a red CaAlSiN₃-based (CASN) phosphor may be used.

In yet a further example, white light sources can be made by combining near ultraviolet emitting laser diodes with a mixture of high efficiency europium based red and blue emitting phosphors plus green emitting copper and aluminum doped zinc sulfide (ZnS:Cu,Al).

In an example, a phosphor or phosphor blend can be selected from a of (Y, Gd, Tb, Sc, Lu, La)₃(Al, Ga, In)₅O₁₂:Ce³⁺, SrGa₂S₄:Eu²⁺, SrS:Eu²⁺, and colloidal quantum dot thin films comprising CdTe, ZnS, ZnSe, ZnTe, CdSe, or CdTe. In an example, a phosphor is capable of emitting substantially red light, wherein the phosphor is selected from a of the group consisting of (Gd,Y,Lu,La)₂O₃:Eu³⁺, Bi³⁺; (Gd,Y,Lu,La)₂O₂S:Eu³⁺, Bi³⁺; (Gd,Y,Lu,La)VO₄:Eu³⁺, Bi³⁺; Y₂(O,S)₃:Eu³⁺; Ca_(1-x)Mo_(1-y)Si_(y)O₄: where 0.05<x<0.5, 0<y<0.1; (Li,Na,K)₅Eu(W,Mo)O₄; (Ca,Sr)S:Eu²⁺; SrY₂S₄:Eu²⁺; CaLa₂S₄:Ce³⁺; (Ca,Sr)S:Eu²⁺; 3.5MgO×0.5MgF₂×GeO₂:Mn⁴⁺ (MFG); (Ba,Sr,Ca)Mg_(x)P₂O₇:Eu²⁺, Mn²⁺; (Y,Lu)₂WO₆:Eu³⁺, Mo⁶⁺; (Ba,Sr,Ca)₃Mg_(x)Si₂O₈:Eu²⁺, Mn²⁺, wherein 1<x<2; (RE_(1-y)Ce_(y))Mg_(2-x)Li_(x)Si_(3-x)P_(x)O₁₂, where RE is at least one of Sc, Lu, Gd, Y, and Tb, 0.0001<x<0.1 and 0.001<y<0.1; (Y, Gd, Lu, La)_(2-x)Eu_(x)W_(1-y)Mo_(y)O₆, where 0.5<x<1.0, 0.01<y<1.0; (SrCa)_(1-x)Eu_(x)Si₅N₈, where 0.01<x<0.3; SrZnO₂:Sm⁺³; M_(m)O_(n)X, wherein M is selected from the group of Sc, Y, a lanthanide, an alkali earth metal and mixtures thereof, X is a halogen; 1<m<3; and 1<n<4, and wherein the lanthanide doping level can range from 0.1 to 40% spectral weight; and Eu³⁺ activated phosphate or borate phosphors; and mixtures thereof. Further details of other phosphor species and related techniques can be found in U.S. Pat. No. 8,956,894, in the name of Raring et al. issued Feb. 17, 2015, and titled “White light devices using non-polar or semipolar gallium containing materials and phosphors”, which is commonly owned, and hereby incorporated by reference herein.

In some embodiments of the present invention, ceramic phosphor materials are embedded in a binder material such as silicone. This configuration is typically less desirable because the binder materials often have poor thermal conductivity, and thus get very hot wherein the rapidly degrade and even burn. Such “embedded” phosphors are often used in dynamic phosphor applications such as color wheels where the spinning wheel cools the phosphor and spreads the excitation spot around the phosphor in a radial pattern.

Sufficient heat dissipation from the phosphor is a critical design consideration for the integrated white light source based on laser diode excitation. Specifically, the optically pumped phosphor system has sources of loss in the phosphor that result is thermal energy and hence must be dissipated to a heat-sink for optimal performance. The two primary sources of loss are the Stokes loss which is a result of converting photons of higher energy to photons of lower energy such that difference in energy is a resulting loss of the system and is dissipated in the form of heat. Additionally, the quantum efficiency or quantum yield measuring the fraction of absorbed photons that are successfully re-emitted is not unity such that there is heat generation from other internal absorption processes related to the non-converted photons. Depending on the excitation wavelength and the converted wavelength, the Stokes loss can lead to greater than 10%, greater than 20%, and greater than 30%, and greater loss of the incident optical power to result in thermal power that must be dissipated. The quantum losses can lead to an additional 10%, greater than 20%, and greater than 30%, and greater of the incident optical power to result in thermal power that must be dissipated. With laser beam powers in the 1 W to 100 W range focused to spot sizes of less than 1 mm in diameter, less than 500 μm in diameter, or even less than 100 μm in diameter, power densities of over 1 W/mm², 100 W/mm², or even over 2,500 W/mm² can be generated. As an example, assuming that the spectrum is comprised of 30% of the blue pump light and 70% of the converted yellow light and a best case scenario on Stokes and quantum losses, we can compute the dissipated power density in the form of heat for a 10% total loss in the phosphor at 0.1 W/mm², 10 W/mm², or even over 250 W/mm². Thus, even for this best-case scenario example, this is a tremendous amount of heat to dissipate. This heat generated within the phosphor under the high intensity laser excitation can limit the phosphor conversion performance, color quality, and lifetime.

For optimal phosphor performance and lifetime, not only should the phosphor material itself have a high thermal conductivity, but it should also be attached to the submount or common support member with a high thermal conductivity joint to transmit the heat away from the phosphor and to a heat-sink. In this invention, the phosphor is attached to a remote submount member that is packaged in a separate assembly. In some embodiments, a heatsink can be used to support the phosphor for release heat generated during wavelength conversion. Ideally the phosphor bond interface will have a substantially large area with a flat surface on both the phosphor side and the support member sides of the interface.

In the present invention, the laser diode output beam must be configured to be incident on the phosphor material to excite the phosphor. In some embodiments the laser beam may be directly incident on the phosphor and in other embodiments the laser beam may interact with an optic, reflector, waveguide, or other object to manipulate the beam prior to incidence on the phosphor. Examples of such optics include, but are not limited to ball lenses, aspheric collimator, aspheric lens, fast or slow axis collimators, dichroic mirrors, turning mirrors, optical isolators, but could be others.

In some embodiments, the apparatus typically has a free space with a non-guided laser beam characteristic transmitting the emission of the laser beam from the laser device to the phosphor material. The laser beam spectral width, wavelength, size, shape, intensity, and polarization are configured to excite the phosphor material. The beam can be configured by positioning it at the precise distance from the phosphor to exploit the beam divergence properties of the laser diode and achieve the desired spot size. In one embodiment, the incident angle from the laser to the phosphor is optimized to achieve a desired beam shape on the phosphor. For example, due to the asymmetry of the laser aperture and the different divergent angles on the fast and slow axis of the beam the spot on the phosphor produced from a laser that is configured normal to the phosphor would be elliptical in shape, typically with the fast axis diameter being larger than the slow axis diameter. To compensate this, the laser beam incident angle on the phosphor can be optimized to stretch the beam in the slow axis direction such that the beam is more circular on phosphor. In other embodiments free space optics such as collimating lenses can be used to shape the beam prior to incidence on the phosphor. The beam can be characterized by a polarization purity of greater than 50% and less than 100%. As used herein, the term “polarization purity” means greater than 50% of the emitted electromagnetic radiation is in a substantially similar polarization state such as the transverse electric (TE) or transverse magnetic (TM) polarization states, but can have other meanings consistent with ordinary meaning.

The white light apparatus also has an electrical input interface configured to couple electrical input power to the laser diode device to generate the laser beam and excite the phosphor material. In an example, the laser beam incident on the phosphor has a power of less than 0.1 W, greater than 0.1 W, greater than 0.5 W, greater than 1 W, greater than 5 W, greater than 10 W, or greater than 20 W. The white light source configured to produce greater than 1 lumen, 10 lumens, 100 lumens, 1000 lumens, 10,000 lumens, or greater of white light output.

The support member is configured to transport thermal energy from the at least one laser diode device and the phosphor material to a heat sink. The support member is configured to provide thermal impedance of less than 10 degrees Celsius per watt, less than 5 degrees Celsius per watt, or less than 3 degrees Celsius per watt of dissipated power characterizing a thermal path from the laser device to a heat sink. The support member is comprised of a thermally conductive material such as copper with a thermal conductivity of about 400 W/(m-K), aluminum with a thermal conductivity of about 200 W/(mK), 4H—SiC with a thermal conductivity of about 370 W/(m-K), 6H—SiC with a thermal conductivity of about 490 W/(m-K), AlN with a thermal conductivity of about 230 W/(m-K), a synthetic diamond with a thermal conductivity of about >1000 W/(m-K), sapphire, or other metals, ceramics, or semiconductors. The support member may be formed from a growth process such as SiC, AlN, or synthetic diamond, and then mechanically shaped by machining, cutting, trimming, or molding. Alternatively, the support member may be formed from a metal such as copper, copper tungsten, aluminum, or other by machining, cutting, trimming, or molding.

Currently, solid state lighting is dominated by systems utilizing blue or violet emitting light emitting diodes (LEDs) to excite phosphors which emit a broader spectrum. The combined spectrum of the so-called pump LEDs and the phosphors can be optimized to yield white light spectra with controllable color point and good color rendering index. Peak wall plug efficiencies for state of the art LEDs are quite high, above 70%, such that LED based white light bulbs are now the leading lighting technology for luminous efficacy. As laser light sources, especially high-power blue laser diodes made from gallium and nitrogen containing material based novel manufacture processes, have shown many advantageous functions on quantum efficiency, power density, modulation rate, surface brightness over conventional LEDs. This opens up the opportunity to use lighting fixtures, lighting systems, displays, projectors and the like based on solid-state light sources as a means of transmitting information with high bandwidth using visible light. It also enables utilizing the modulated laser signal or direct laser light spot manipulation to measure and or interact with the surrounding environment, transmit data to other electronic systems and respond dynamically to inputs from various sensors. Such applications are herein referred to as “smart lighting” applications.

In some embodiments, the present invention provides novel uses and configurations of gallium and nitrogen containing laser diodes in communication systems such as visible light communication systems. More specifically the present invention provides communication systems related to smart lighting applications with gallium-and-nitrogen-based lasers light sources coupled to one or more sensors with a feedback loop or control circuitry to trigger the light source to react with one or more predetermined responses and combinations of smart lighting and visible light communication. In these systems, light is generated using laser devices which are powered by one or more laser drivers. In some embodiments, individual laser devices are used and optical elements are provided to combine the red, green and blue spectra into a white light spectrum. In other embodiments, blue or violet laser light is provided by a laser source and is partially or fully converted by a wavelength converting element into a broader spectrum of longer wavelength light such that a white light spectrum is produced.

The blue or violet laser devices illuminate a wavelength converting element which absorbs part of the pump light and reemits a broader spectrum of longer wavelength light. The light absorbed by the wavelength converting element is referred to as the “pump” light. The light engine is configured such that some portion of both light from the wavelength converting element and the unconverted pump light are emitted from the light-engine. When the non-converted, blue pump light and the longer wavelength light emitted by the wavelength converting element are combined, they may form a white light spectrum. In an example, the partially converted light emitted generated in the wavelength conversion element results in a color point, which is white in appearance. In an example, the color point of the white light is located on the Planckian blackbody locus of points. In an example, the color point of the white light is located within du′v′ of less than 0.010 of the Planckian blackbody locus of points. In an example, the color point of the white light is preferably located within du′v′ of less than 0.03 of the Planckian blackbody locus of points.

In an example, the wavelength conversion element is a phosphor which contains garnet host material and a doping element. In an example, the wavelength conversion element is a phosphor, which contains an yttrium aluminum garnet host material and a rare earth doping element, and others. In an example, the wavelength conversion element is a phosphor which contains a rare earth doping element, selected from one or more of Nd, Cr, Er, Yb, Nd, Ho, Tm Cr, Dy, Sm, Tb and Ce, combinations thereof, and the like. In an example, the wavelength conversion element is a phosphor which contains oxy-nitrides containing one or more of Ca, Sr, Ba, Si, Al with or without rare-earth doping. In an example, the wavelength conversion element is a phosphor which contains alkaline earth silicates such as M₂SiO₄:Eu²⁺ (where M is one or more of Ba²⁺, Sr²⁺ and Ca²⁺). In an example, the wavelength conversion element is a phosphor which contains Sr₂LaAlO₅:Ce³⁺, Sr₃SiO₅:Ce³⁺ or Mn⁴⁺-doped fluoride phosphors. In an example, the wavelength conversion element is a high-density phosphor element. In an example, the wavelength conversion element is a high-density phosphor element with density greater than 90% of pure host crystal. In an example, the wavelength converting material is a powder. In an example, the wavelength converting material is a powder suspended or embedded in a glass, ceramic or polymer matrix. In an example, the wavelength converting material is a single crystalline member. In an example, the wavelength converting material is a powder sintered to density of greater than 75% of the fully dense material. In an example, the wavelength converting material is a sintered mix of powders with varying composition and/or index of refraction. In an example, the wavelength converting element is one or more species of phosphor powder or granules suspended in a glassy or polymer matrix. In an example, the wavelength conversion element is a semiconductor. In an example, the wavelength conversion element contains quantum dots of semiconducting material. In an example, the wavelength conversion element is comprised by semiconducting powder or granules.

For laser diodes the phosphor may be remote from the laser die, enabling the phosphor to be well heat sunk, enabling high input power density. This is an advantageous configuration relative to LEDs, where the phosphor is typically in contact with the LED die. While remote-phosphor LEDs do exist, because of the large area and wide emission angle of LEDs, remote phosphors for LEDs have the disadvantage of requiring significantly larger volumes of phosphor to efficiently absorb and convert all of the LED light, resulting in white light emitters with large emitting areas and low luminance.

For LEDs, the phosphor emits back into the LED die where the light from the phosphor can be lost due to absorption. For laser diode modules, the environment of the phosphor can be independently tailored to result in high efficiency with little or no added cost. Phosphor optimization for laser diode modules can include highly transparent, non-scattering, ceramic phosphor plates. Decreased temperature sensitivity can be determined by doping levels. A reflector can be added to the backside of a ceramic phosphor, reducing loss. The phosphor can be shaped to increase in-coupling and reduce back reflections. Of course, there can be additional variations, modifications, and alternatives.

For laser diodes, the phosphor or wavelength converting element can be operated in either a transmission or reflection mode. In a transmission mode, the laser light is shown through the wavelength converting element. The white light spectrum from a transmission mode device is the combination of laser light not absorbed by the phosphor and the spectrum emitted by the wavelength converting element. In a reflection mode, the laser light is incident on the first surface of the wavelength converting element. Some fraction of the laser light is reflected off of the first surface by a combination of specular and diffuse reflection. Some fraction of the laser light enters the phosphor and is absorbed and converted into longer wavelength light. The white light spectrum emitted by the reflection mode device is comprised by the spectrum from the wavelength converting element, the fraction of the laser light diffusely reflected from the first surface of the wavelength converting element and any laser light scattered from the interior of the wavelength converting element.

In a specific embodiment, the laser light illuminates the wavelength converting element in a reflection mode. That is, the laser light is incident on and collected from the same side of the wavelength converting element. The element may be heat sunk to the emitter package or actively cooled. Rough surface is for scattering and smooth surface is for specular reflection. In some cases, such as with a single crystal phosphor a rough surface with or without an AR coating of the wavelength converting element is provided to get majority of excitation light into phosphor for conversion and Lambertian emission while scattering some of the excitation light from the surface with a similar Lambertian as the emitted converted light. In other embodiments such as ceramic phosphors with internal built-in scattering centers are used as the wavelength converting elements, a smooth surface is provided to allow all laser excitation light into the phosphor where blue and wavelength converted light exits with a similar Lambertian pattern.

In a specific embodiment, the laser light illuminates the wavelength converting element in a transmission mode. That is, the laser light is incident on one side of the element, traverses through the phosphor, is partially absorbed by the element and is collected from the opposite side of the phosphor.

The wavelength converting elements, in general, can themselves contain scattering elements. When laser light is absorbed by the wavelength converting element, the longer wavelength light that is emitted by the element is emitted across a broad range of directions. In both transmission and reflection modes, the incident laser light must be scattered into a similar angular distribution in order to ensure that the resulting white light spectrum is substantially the same when viewed from all points on the collecting optical elements. Scattering elements may be added to the wavelength converting element in order to ensure the laser light is sufficiently scattered. Such scattering elements may include: low index inclusions such as voids, spatial variation in the optical index of the wavelength converting element which could be provided as an example by suspending particles of phosphor in a matrix of a different index or sintering particles of differing composition and refractive index together, texturing of the first or second surface of the wavelength converting element, and the like.

In a specific embodiment, a laser or SLED driver module is provided. For example, the laser driver module generates a drive current, with the drive currents being adapted to drive a laser diode to transmit one or more signals such as digitally encoded frames of images, digital or analog encodings of audio and video recordings or any sequences of binary values. In a specific embodiment, the laser driver module is configured to generate pulse-modulated signals at a frequency range of about 50 to 300 MHz, 300 MHz to 1 GHz or 1 GHz to 100 GHz. In another embodiment the laser driver module is configured to generate multiple, independent pulse-modulated signal at a frequency range of about 50 to 300 MHz, 200 MHz to 1 GHz or 1 GHz to 100 GHz. In an embodiment, the laser driver signal can be modulated by an analog voltage or current signal.

FIG. 8A is a functional block diagram for a laser-based white light source containing a blue pump laser and a wavelength converting element according to an embodiment of the present invention. In some embodiments, the white light source is used as a “light engine” for static lighting, dynamic light, VLC, or smart lighting applications. Referring to FIG. 8A, a blue or violet laser device 1202 emitting a spectrum with a center point wavelength between 390 and 480 nm is provided. The light from the blue laser device 1202 is incident on a wavelength converting element 1203 which partially or fully converts the blue light into a broader spectrum of longer wavelength light such that a white light spectrum is produced. A laser driver 1201 is provided which powers the laser device 1202. In a preferred embodiment the laser diode device is a gallium and nitrogen containing laser diode device operating in the 395 nm to 425 nm wavelength range, 425 nm to 490 nm wavelength range, or 490 nm to 550 nm range. For example, the laser diode is a blue laser diode with an output power of less than 1 W, or about 1 W to about 4 W, or about 4 W to about 10 W. In some embodiments, one or more beam shaping optical elements 1204 may be provided in order to shape or focus the white light spectrum. Optionally, the one or more beam shaping optical elements 1204 can be one selected from slow axis collimating lens, fast axis collimating lens, aspheric lens, ball lens, total internal reflector (TIR) optics, parabolic lens optics, refractive optics, or a combination of above. In other embodiments, the one or more beam shaping optical elements 1204 can be disposed prior to the laser light incident to the wavelength converting element 1203.

FIG. 8B is a functional block diagram for a laser-based white light source containing multiple blue pump lasers and a wavelength converting element according to another embodiment of the present invention. Referring to FIG. 8B, a laser driver 1205 is provided, which delivers a delivers a controlled amount of current at a sufficiently high voltage to operate three laser diodes 1206, 1207 and 1208. In a preferred embodiment the laser diode devices are gallium and nitrogen containing laser diode devices operating in the 395 nm to 425 nm wavelength range, 425 nm to 490 nm wavelength range, or 490 nm to 550 nm range. For example, the three laser diodes are blue laser diodes with an aggregated output power of less than 1 W, or about 1 W to about 6 W, or about 6 W to about 12 W, or about 12 W to 30 W. The three blue laser devices 1206, 1207 and 1208 are configured to have their emitted light to be incident on a wavelength converting element 1209 in either a transmission or reflection mode. The wavelength converting element 1209 absorbs a part or all the blue laser light and emits photons with longer wavelengths. The spectra emitted by the wavelength converting element 1209 and any remaining laser light are collected by beam shaping optical elements 1210, such as lenses or mirrors, which direct the light with a preferred direction and beam shape. Optionally, the wavelength converting element 1209 is a phosphor-based material. Optionally, more than one wavelength converting elements can be used. Optionally, the bean shaping optical elements can be one or a combination of more selected the list of slow axis collimating lens, fast axis collimating lens, aspheric lens, ball lens, total internal reflector (TIR) optics, parabolic lens optics, refractive optics, and others. Optionally, the beam shaping optical element is implemented before the laser light hits the wavelength converting element.

In another embodiment, an optical fiber is used as the waveguide element wherein on one end of the fiber the electromagnetic radiation from the one or more laser diodes is in-coupled to enter the fiber and on the other end of the fiber the electromagnetic radiation is out-coupled to exit the fiber wherein it is then incident on the phosphor member. The optical fiber could have a transport length ranging from 100 μm to about 100 m, or to about 1 km, or greater. The optical fiber could be comprised of a single mode fiber (SMF) or a multi-mode fiber (MMF), with core diameters ranging from about 1 μm to 10 μm, about 10 μm to 50 μm, about 50 μm to 150 μm, about 150 μm to 500 μm, about 500 μm to 1 mm, or greater than 1 mm. The optical core material may consist of a glass such as silica glass wherein the silica glass could be doped with various constituents and have a predetermined level of hydroxyl groups (OH) for an optimized propagation loss characteristic. The glass fiber material may also be comprised of a fluoride glass, a phosphate glass, or a chalcogenide glass. In an alternative embodiment, a plastic optical fiber is used to transport the laser pump light.

FIG. 9A is a functional block diagram for a laser-induced fiber-delivered white light source according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, the laser-induced fiber-delivered white light source has a laser driver 1211 configured to provide one or more driving currents or voltages or modulation control signals. The laser-induced fiber-delivered white light source also includes at least one blue laser device 1212 configured to emit a laser light with a blue wavelength in a range from about 385 nm to about 485 nm. Optionally, the at least one laser diode device 1212 is a LD chip configured as a chip-on-submount form having a Gallium and Nitrogen containing emitting region operating in one wavelength selected from 395 nm to 425 nm wavelength range, 425 nm to 490 nm wavelength range, and 490 nm to 550 nm range. Optionally, the at least one laser diode device 1212 includes a set of multiple laser diode (LD) chips. Each includes an GaN-based emission stripe configured to be driven by independent driving current or voltage from the laser driver 1211 to emit a laser light. All emitted light from the multiple LD chips can be combined to one beam of electromagnetic radiation. Optionally, the multiple LD chips are blue laser diodes with an aggregated output power of less than 1 W, or about 1 W to about 10 W, or about 10 W to about 30 W, or about 30 W to 100 W, or greater. Optionally, each emitted light is driven and guided separately.

In the embodiment, the laser-induced fiber-delivered white light source includes a waveguide device 1214 configured to couple and deliver the laser light from the at least one laser diode device 1212 to a remote destination. Optionally, the waveguide device 1214 is an optical fiber for being relatively flexibly disposed in any custom-designed light system. The optical fiber includes a single mode fiber or multiple mode fiber with a core diameter in a range selected from about 1 μm to 10 μm, about 10 μm to 50 μm, about 50 μm to 150 μm, about 150 μm to 500 μm, about 500 μm to 1 mm, or greater than 1 mm. Optionally, the waveguide device 1214 is a semiconductor waveguide pre-fabricated on a semiconductor substrate to fit a relative flexible light path in any custom-designed light system. The waveguide device 1214 can have an arbitrary length to deliver the laser electromagnetic radiation through a waveguide transport member which terminate at a light head member disposed at the remote destination. Optionally, the laser light exiting the light head is characterized by a beam diameter ranging from 1 μm to 5 mm and a divergence ranging from 0 degree to 200 degrees full angle.

In the embodiment, the laser-induced fiber-delivered white light source also includes a wavelength converting element 1215 disposed in the light head member at the remote destination. Optionally, the wavelength converting element 1215 is a phosphor material configured to be a single plate or a pixelated plate disposed on a submount material completely separated from the laser diode device 1212. Optionally, the phosphor material used in the fiber-delivered laser lighting system is comprised of a ceramic yttrium aluminum garnet (YAG) doped with Ce or a single crystal YAG doped with Ce or a powdered YAG comprising a binder material. The phosphor material is configured to convert at least partially the incoming laser electromagnetic radiation of a first wavelength (e.g., in blue spectrum) to a phosphor emission of a second wavelength. The second wavelength is longer than the first wavelength. Optionally, the second wavelength is in yellow spectrum range. Optionally, the phosphor material has an optical conversion efficiency of greater than 50 lumen per optical watt, greater than 100 lumen per optical watt, greater than 200 lumen per optical watt, or greater than 300 lumen per optical watt.

Optionally, the phosphor material 1215 has a surface being placed at a proximity of the end section of the optical fiber or semiconductor waveguide in the light head member to receive the laser electromagnetic radiation exited from the waveguide device 1214. Optionally, the laser electromagnetic radiation has a primary propagation direction which is configured to be in an angle of incidence with respect to an axis of the surface of the phosphor material in a range from 20 degrees to close to 90 degrees. Optionally, the angle of incidence of the laser electromagnetic radiation is limited in 25 to 35 degrees. Optionally, the angle of incidence of the laser electromagnetic radiation is limited in 35 to 40 degrees. Optionally, the angle of incidence of the laser electromagnetic radiation is limited in 40 to 45 degrees. Optionally, the end section of the waveguide device 1214 in the light head member is disposed in a close proximity relative to the surface of phosphor material so that laser electromagnetic radiation can land on the surface to form an excitation spot in a range of 25 μm to 5 mm. Optionally, the excitation spot is limited within 50 μm to 500 μm. The laser electromagnetic radiation at the excitation spot is absorbed by the phosphor material to induce a phosphor emission with a spectrum of longer wavelengths than the first wavelength of the incoming electromagnetic radiation. A combination of the phosphor emission of a second wavelength plus a partial mixture with the laser electromagnetic radiation of the first wavelength produces a white light emission. Optionally, the white light emission is substantially reflected from the surface of the phosphor material and redirected or shaped as a white light beam used for various applications. Optionally, the white light emission out of the phosphor material can be in a range selected from 10 to 100 lm, 100 to 500 lm, 500 to 1000 lm, 1000 to 3000 lm, and greater than 3000 lm. Alternatively, the white light emission out of the light head member as a white light source with a luminance of 100 to 500 cd/mm², 500 to 1000 cd/mm², 1000 to 2000 cd/mm², 2000 to 5000 cd/mm², and greater than 5000 cd/mm².

FIG. 9B is a functional block diagram for a laser-induced fiber-delivered white light source according to another embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, the laser-induced fiber-delivered white light source includes a blue laser device 1222 driven by a laser driver 1221 to emit a laser light with a blue emission characterized by a wavelength ranging from 395 nm to 550 nm. Optionally, the laser device is a laser diode (LD) chip configured as a Chip-on-submount form with a GaN-based emitting region operating in a first wavelength selected from 395 nm to 425 nm wavelength range, 425 nm to 490 nm wavelength range, and 490 nm to 550 nm range. The laser light exits the emitting region as a beam of electromagnetic radiation with relatively large divergence.

Optionally, the laser-induced fiber-delivered white light source includes one or more beam collimation and focus elements 1223 configured to confine or shape the beam of electromagnetic radiation. The one or more beam collimation and focus elements 1223 may include a collimation lens, a focus lens, a filter, a beam splitter for guiding the beam of electromagnetic radiation to a specific direction with reduced beam diameter and smaller divergence. In the embodiment, the laser-induced fiber-delivered white light source also includes a waveguide device 1224. Optionally, the waveguide device 1224 is substantially similar to the waveguide device 1214 described in earlier sections. The waveguide device 1224 is configured to receive the laser beam with proper alignment to an output port of the laser package holding the blue laser device 1222 to couple the laser electromagnetic radiation into a narrowed light path in sufficiently high efficiency greater than 60% or even greater than 80%. The waveguide device 1224 is configured to deliver the laser electromagnetic radiation to a remote destination for various specific applications.

In the embodiment, the laser-induced fiber-delivered white light source further includes a wavelength converting element 1225. Optionally, the wavelength converting element 1225 includes at least a phosphor material disposed in a remote location completely separated from the laser devices and is able to receive the laser electromagnetic radiation exiting the waveguide device 1224. The laser electromagnetic radiation interacts with the phosphor material within an excitation spot to induce a phosphor emission which has a second wavelength that is longer than the first wavelength of the laser electromagnetic radiation. A mixture of a portion of laser electromagnetic radiation of the first wavelength with the phosphor emission of the second wavelength produces a white light emission. The white light emission is used for many illumination and projection applications statically and dynamically. Optionally, the white light emission out of the phosphor material is achieved in 10 to 100 lm, 100 to 500 lm, 500 to 1000 lm, 1000 to 3000 lm, and greater than 3000 lm. Alternatively, the white light emission generated by the laser induced has a luminance of 100 to 500 cd/mm², 500 to 1000 cd/mm², 1000 to 2000 cd/mm², 2000 to 5000 cd/mm², and greater than 5000 cd/mm².

FIG. 9C is a functional block diagram for a multi-laser-based fiber-delivered white light source according to yet another embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, the multi-laser-based fiber-delivered white light source includes a first blue laser device 1232, a second blue laser device 1233, and a third blue laser device 1234, commonly driven by a laser driver 1231. Optionally, there can be more than three laser devices driven by one or more laser drivers. Optionally, each laser device is configured to emit a laser light with a blue emission in one wavelength ranging from 395 nm to 550 nm. Optionally, the wavelength range can be limited in one selected from 395 nm to 425 nm wavelength range, 425 nm to 490 nm wavelength range, and 490 nm to 550 nm range. Optionally, each blue laser device, 1232, 1233, and 1234, includes a laser diode (LD) chip configured in Chip-on-submount form with a Gallium and Nitrogen containing emitting region to emit the blue laser light. Optionally, all emitted blue laser light from the multiple laser diode devices can be combined to one laser beam by one or more beam coupling elements 1235. Optionally, the one combined laser beam of the multi-laser-based filter delivered white light source is configured to provide a beam of electromagnetic radiation of a first wavelength in blue spectrum with an aggregated output power of less than 1 W, or about 1 W to about 10 W, or about 10 W to about 30 W, or greater.

In the embodiment, the multi-laser-based fiber-delivered white light source includes a fiber assembly 1236 configured to align fiber core to the combined laser beam of electromagnetic radiation so that the about 60% or greater, or 80% or greater efficiency of the combined laser beam of electromagnetic radiation can be coupled into an optical fiber embedded within the fiber assembly 1236. The fiber assembly 1236 is substantially similar the waveguide device 1214 and 1224 for delivering the laser electromagnetic radiation to a remote destination via a flexible or customized light path in the optical fiber with an arbitrary length (e.g., over 100 m). At the end of the optical fiber, the laser electromagnetic radiation of the first wavelength exits with a confined beam diameter and restricted divergence.

In the embodiment, the multi-laser-based fiber-delivered white light source includes a wavelength converting element 1237 disposed in a light head member at the remote destination to receive the laser beam exiting an end section of the optical fiber. In a specific embodiment, the wavelength converting element 1237 includes a phosphor plate or a pixelated phosphor plate disposed in the light head member at proximity of the end section of the optical fiber so that the beam of electromagnetic radiation exited the optical fiber can land in an spot on an surface of the phosphor plate with a spot size limited in a range of about 50 μm to 5 mm. Optionally, the phosphor plate used in the fiber-delivered laser lighting system is comprised of a ceramic yttrium aluminum garnet (YAG) doped with Ce or a single crystal YAG doped with Ce or a powdered YAG comprising a binder material. The phosphor plate has an optical conversion efficiency of greater than 50 lumen per optical watt, greater than 100 lumen per optical watt, greater than 200 lumen per optical watt, or greater than 300 lumen per optical watt. The phosphor plate absorbs the blue emission lasering the beam of electromagnetic radiation of the first wavelength to induce a phosphor emission of a second wavelength in yellow or violet spectra range. Optionally, the phosphor emission of the second wavelength is partially mixed with a portion of the incoming/reflecting beam of electromagnetic radiation of the first wavelength to produce a white light beam. Optionally, the light head member is configured to set the relative position of the end section of the optical fiber on a sloped body to make an angle of incidence of the exiting electromagnetic radiation with respect to an axis of the surface of the phosphor plate in a range from 5 degrees to 90 degrees. Optionally, the angle of incidence is narrowed in a smaller range from 25 degrees to 35 degrees or from 35 degrees to 40 degrees. Optionally, the white light emission is sufficiently reflected out of the phosphor plate.

In the embodiment, the multi-laser-based fiber-delivered white light source optionally includes one or more beam shaping optical elements 1238. In an embodiment, the one or more beam shaping optical elements 1238 includes a light head member which provides a mechanical fixture for holding the end section of the optical fiber for outputting the laser electromagnetic radiation and supporting the phosphor plate via a submount. Optionally, the mechanical fixture includes a sloped metal body to support the end section of the optical fiber in an angled direction with respect to the phosphor plate which is disposed at a bottom region of the sloped metal body. Optionally, the mechanical fixture includes a heatsink associated with the submount to support the phosphor plate for facilitating heat conduction from the hot phosphor material to the heatsink during a heated wavelength conversion process when the laser beam with high power illuminates in a small excitation spot on the surface of the phosphor plate. Optionally, the mechanical fixture includes a reflecting semi-cone structure for facilitating collection of the white light emission from the surface of the phosphor plate. In another embodiment, the one or more beam shaping optical elements 1238 includes additional secondary optics elements for handling the white light emission generated by the multi-laser-based fiber-delivered white light source. These secondary optics elements include static free-space optical elements, fiber-based optical elements, semiconductor-based optical elements, or one or more optical elements that are dynamically controlled for providing smart lighting information or information projection.

FIG. 10A is a simplified diagram illustrating multiple discrete lasers configured with an optical combiner according to embodiments of the present invention. As shown, the diagram includes a package or enclosure for multiple laser diode light emitting devices. In a preferred embodiment the laser diode light-emitting devices are gallium and nitrogen containing laser diode devices operating in the 395 nm to 425 nm wavelength range, 425 nm to 490 nm wavelength range, or 490 nm to 550 nm range. For example, the multiple laser diode emitters are blue laser diodes with an aggregated output power of less than 1 W, or about 1 W to about 10 W, or about 10 W to about 30 W, or about 30 W to 100 W, or greater. Each of the devices is configured on a single ceramic or multiple chips on a ceramic, which are disposed on common heat sink. As shown, the package includes all free optics coupling, collimators, mirrors, spatially or polarization multiplexed for free space output or refocused in a fiber or other waveguide medium. As an example, the package has a low profile and may include a flat pack ceramic multilayer or single layer. The layer may include a copper, a copper tungsten base such as butterfly package or covered CT mount, Q-mount, or others. In a specific embodiment, the laser devices are soldered on CTE matched material with low thermal resistance (e.g., AlN, diamond, diamond compound) and forms a sub-assembled chip on ceramics. The sub-assembled chip is then assembled together on a second material with low thermal resistance such as copper including, for example, active cooling (i.e., simple water channels or micro channels), or forming directly the base of the package equipped with all connections such as pins. The flatpack is equipped with an optical interface such as window, free space optics, connector or fiber to guide the light generated and a cover environmentally protective.

FIG. 10B is an example of enclosed free space laser module. A case 1400 is used for assembling a free-space mirror-based laser combiner. The laser module includes two electrical supply pins 1410 for providing driving voltages for the laser diodes 1430. In a preferred embodiment the laser diode devices are gallium and nitrogen containing laser diode devices operating in the 395 nm to 425 nm wavelength range, 425 nm to 490 nm wavelength range, or 490 nm to 550 nm range. For example, the multiple laser diode emitters are blue laser diodes with an aggregated output power of less than 1 W, or about 1 W to about 10 W, or about 10 W to about 30 W, or greater. The case 1400 includes a hole for a fiber 1460 to couple with the light guide output combined from all laser diodes 1430 through the series of mirrors 1450. An access lid 1420 is designed for easy access of free-space optical elements 1440 in the assembly. A compact plug-and-play design provides a lot of flexibilities and ease of use.

FIG. 10C is a schematic of an enclosed free space multi-chip laser module with an extended delivery fiber plus phosphor converter according to a specific embodiment of the present invention. As shown, the enclosed free space multi-chip laser module is substantially similar to the one shown in FIG. 10A with two electrical supply pins 1410 to produce a laser light beam in violet or blue light spectrum. The multiple laser chips 1430 in the package equipped with free-space optics units 1455 provide substantially high intensity for the light source that is desired for many new applications. Additionally, an extended optical fiber 1465 with one end is coupled with the light guide output for further guiding the laser light beam to a desired distance for certain applications up to 100 m or greater. Optionally, the optical fiber can be also replaced by multiple waveguides built in a planar structure for adapting silicon photonics integration. At the other end of the optical fiber, a phosphor-based wavelength converter 1470 may be disposed to receive the laser light, where the violet or blue color laser light is converted to white color light 1475 and emitted out through an aperture or collimation device. As a result, a white light source with small size, remote pump, and flexible setup is provided.

FIG. 11 is a perspective view of a fiber-delivered white light source including a general laser package and a light head member including a wavelength conversion phosphor member wherein the laser package and the light head member are linked to each other via a fiber assembly according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, a fiber-delivered white light source 1500 includes at least a general laser package 1510 for laser and a light head member 1520 connected by a fiber assembly 1530. The general laser package 1510 is a metal case for enclosing a laser module therein having an electrical connector 1512 disposed through a cover member 1511 for providing electrical supply to the devices in the case. The bottom side (not visible) is for mounting to a heat conductive base for distributing heat out of the heat-generating laser device. The light head member 1520 is metal case with a sloped shape and a glass window 1522 covering the slopped facet, enclosing a phosphor material inside (not shown) for receiving laser light delivered by the fiber assembly 1530 and converting the laser emission to a white light emission. The bottom side (not visible) od the light head member 1530 is made by metal or other thermal conductive material for efficiently distributing heat generated by the phosphor material therein. The fiber assembly 1530 shown in FIG. 11 is visible with a semi-flexible metal armor used to protect the optical fiber inside throughout an extended length from a first end coupled to the general laser package 1510 and a second end coupled with the light head member 1520 at a remote destination. The extended length can be over 100 m.

FIG. 12 is a top view of the general laser package of FIG. 11 according to the embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, the electrical connector 1512 with multiple pins are disposed via an electrical feedthrough at the top cover member 1511 of the general package 1510. The opposite side of the general laser package is bottom member used for mounting the general laser package 1510 in applications. The bottom member is preferred to be made by metal material, for example, AlN, AlO, BeO, Diamond, CuW, Cu, or Silver, or other high thermal conductive materials for mounting on a heatsink to quickly distributing heat generated by laser devices inside the package 1510.

FIG. 13 is a top view of interior elements of the general laser package of FIG. 12 including a blue-laser module mounted on an electronic circuit board according to the embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. The general laser package 1510B of FIG. 13 is substantially the same general laser package 1510 of FIG. 12 with the top cover member 1511 being removed. As shown, the general laser package 1510B encloses a board member 1515 on which the electrical connector 1512 and multiple resistors and capacitors or other electronic components are mounted. Primarily, a blue-laser module 1580 is disposed in a center region with multiple electrical pins plugged into the board member 1515. A fixing member 1516 is placed on top of the blue-laser module 1580 for securing the mounting of the blue-laser module 1580. An output port 1587 is coupled to the blue-laser module 1580 from one side thereof and also coupled to the fiber assembly (with the metal armor of the optical fiber being partially visible). In the embodiment, the blue-laser module 1580 is configured to generate high-power laser light for the fiber-delivered white light source 1500 (FIG. 11). For example, the blue laser module contains one or more laser diode chips with gallium and nitrogen containing emitting region configured to generate a laser electromagnetic radiation of a first wavelength in blue spectrum range with a power less than 1 W, or about 1 W to about 3 W, or about 3 W to about 10 W, or about 10 W to 100 W, or greater than 100 W.

FIG. 14 is a top view of the blue-laser module with opened lid according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, the blue-laser module 1800 is configured as a metal case 1801 (with lid opened) enclosing a support member 1802 for supporting multiple components: at least one laser diode device 1810, a collimating lens 1820, a thermistor 1830, a beam splitter 1840, a first photodetector 1850, a focus lens 1860, an output port 1870, and a second photodetector 1880. Optionally, the laser diode device 1810 is a configured to be a chip-on-submount (CoS) device having a Gallium and Nitrogen (GaN) containing active region which is driven to generate a laser light with primary emission spectrum in blue region ranging from 415 nm to 485 nm. Optionally, the laser diode device 1810 is mounted on a ceramic base member on the support member 1802. In an embodiment, the ceramic base member is a High Temperature Co-fired Ceramic (HTCC) submount structure configured to embed electrical conductors therein for connecting the laser diode with its driver, and to provide sufficiently efficient thermal conduction for the laser diode during operation.

In an embodiment, the laser light generated by the laser diode device 1810 exits with a large spread into a collimating lens 1820 to form a laser beam with a reduced spot size and a narrowed spread range. Optionally, the collimating lens 1820 is disposed in front of an exit facet of the GaN active region of the CoS chip 1810 and fixed by a weld clip. A thermistor 1830 is disposed near the laser diode device 1810 as a temperature sensor for monitoring temperature during operation. Optionally, an electrostatic discharge (ESD) Zener diode is included to protect the laser diode device from static electrical shock.

In the embodiment, the beam splitter 1840 is disposed in the path of the collimated laser beam. Optionally, the beam splitter 1840 is a filter. Optionally, beam splitter 1840 is an optical crystal with a front facet and a back facet. The front facet of the beam splitter faces the incoming laser beam and is coated with an anti-reflection thin-film for enhancing transmission. Optionally, a small amount of laser light still is reflected. The first photodetector 1850 is placed (to the left) to detect the reflected light. Optionally, the photodiode 1850 is the first photodetector characterized to detect primarily blue emission for safety sensing of the laser diode device 1810. The back facet of the beam splitter allows that a primary first portion of the laser beam is exited in a first direction while a minor second portion with the blue emission being substantially filtered is split to a second direction deviated from the first direction. The second photodetector 1880 is placed (to the right) to detect yellow spectrum for monitoring the second portion of the laser beam with the blue emission being substantially filtered. Optionally, an extra filter is placed in front of the second photodetector 1880.

In the embodiment, the primary first portion of the laser beam exited from the beam splitter 1840 is led to a focus lens 1860 disposed inside the metal case 1801. Optionally, the focus lens 1860 is configured to confine the laser beam to much smaller size that can be coupled into an optical fiber. Optionally, the Optionally, the coupling efficiency of the laser beam into the optical fiber is achieved and maintained greater than 80%. Optionally, the focus lens 1860 is mounted to the output port 1870 from inside of the metal case 1801. The optical port 1870 is 360-degree laser weld in a through hole at one side wall of the metal case 1801. Referring to FIG. 13, a first end of the fiber assembly 1530 is configured to couple with the output port which is denoted as 1587.

In the embodiment, the blue-laser module 1800 also includes multiple pins 1890 that are disposed at two opposite sides of the metal case 1801. One end of each pin is connected to the electrical connector embedded in the ceramic base member. Another end of each pin is bended down to plug into the board member 1515 (see FIG. 13) so that the blue-laser module 1800 can receive electrical driver/control signals.

FIG. 15 is a perspective view of the blue-laser module according to the embodiment of the present invention. Referring to FIG. 15, it shows a substantially same blue-laser module of FIG. 14 for better illustrating the structural layout of each components mentioned herein.

FIG. 16 is (A) a top view of a general laser package, (B) a top view of interior elements of the general laser package including a blue-laser module, and (C) a top view of the blue-laser module according to another embodiment of the present invention. These diagrams are merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. In the embodiment shown in the FIG. 16, in part A, the top cover member 2011 of a general laser package 2010 is seen with an electrical connector 2012 disposed therein. An output port 2017 is configured to couple with a fiber assembly. In part B, the general laser package 2010B is shown without the top cover member 2011. The electrical connector 2012 is seen mounted on a board member 2015. A blue-laser module 2080 is partially visible is also mounted on the board member 2015 with several pins visibly located at two opposite sides while a large piece of fixing clip 2016 is placed on top of the blue-laser module 2080. A focus lens 2087 is disposed outside the blue-laser module 2080 and coupled with the fiber assembly at the output port 2017 (see part A). In part C, the blue-laser module 2080 is shown as a metal case 2081 with its lid opened. The blue-laser module 2080 in the embodiment includes at least a laser diode device 2082 disposed on a support member 2087 to generate a laser light, a collimating lens 2088 disposed and aligned to one facet of an emitting stripe of the laser diode device 2082 in an optical path of the laser light, and a beam splitter 2084 disposed down-stream of the optical path of the laser light. Optionally, multiple laser diode devices configured respectively as Chip-on-Submount LD chips can be laid in the metal case 2081 of the blue-laser module for achieving higher laser power. Optionally, multiple laser beams from multiple LD chips can be combined to reach unified power of 6 W, or 12 W, or 15 W for obtaining a brighter white light.

In the embodiment, the laser diode device 2082 includes an active region made by Gallium Nitride having the emitting stripe configured to emit light from one end facet. Optionally, the emitted light is substantially a blue emission with a wavelength in a range from 415 nm to 485 nm. The support member 2087 optionally is a High Temperature Co-fired Ceramic (HTCC) submount structure configured to embed electrical conducting wires therein. This type of ceramic support member provides high thermal conductivity for efficiently dissipating heat generated by the laser diode 2082 to a heatsink that is made to contact with the support member 2087. The ceramic support member 2087 also can allow optimized conduction wire layout so that ESD can be prevented and thermal management of the whole module can be improved. Referring to part C of FIG. 16, at least two electrical pins 2089 are configured to connect with the conducting wires in the HTTC ceramic submount structure for providing external drive signals for the laser diode 2082. Optionally, the blue-laser module 2080 includes a temperature sensor 2083 that can be disposed within the metal case on the support member and relative far away from the location of the laser diode 2082.

In the embodiment, the light generated by the laser diode device 2082 is led into the collimating lens 2088 so that the light can be confined with a smaller spread range to form a laser beam along a first direction (x). Optionally, the beam splitter 2084 is disposed down stream of an optical path along the first direction x, and is configured to split the laser beam to at least a first portion primarily in the first direction x and a second portion redirected to a second direction y. The first portion of the laser beam remains primarily a blue emission. The second portion may be filtered to eliminate the blue spectrum while retaining minor yellow spectrum. In the embodiment, the blue-laser module 2080 further includes a photo diode 2085 disposed in the path of the second direction y inside the metal case 2081 to detect the yellow spectrum.

FIG. 17 is a partial cross-sectional view of a fiber assembly according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, in an embodiment, the end section of the fiber assembly 1700 is supposed to be coupled with the laser module 1800 (see FIG. 15). An optical fiber 1701 is embedded in the fiber assembly 1700. Optionally, the optical fiber 1701 is comprised of a single mode fiber (SMF) or a multi-mode fiber (MMF), with core diameters ranging from about 1 um to 10 um, about 10 um to 50 um, about 50 um to 150 um, about 150 um to 500 um, about 500 um to 1 mm, or greater than 1 mm. The optical core material may consist of a glass such as silica glass wherein the silica glass could be doped with various constituents and have a predetermined level of hydroxyl groups (OH) for an optimized propagation loss characteristic. The glass fiber material may also be comprised of a fluoride glass, a phosphate glass, or a chalcogenide glass. In an alternative embodiment, a plastic optical fiber is used to transport the laser pump light. Optionally, most part of the optical fiber in a middle section of the fiber assembly 1700 is protected by a fiber jacket. FIG. 17 shows that an end section of the fiber assembly in a ferrule 1702 is terminated in a fiber termination adaptor 1710. Optionally, the ferrule 1702 can be made by glass, or ceramic material, or metal material. Referring to FIG. 15 and FIG. 17, the fiber termination adaptor 1710 is coupled with an output port by laser welding. In a specific embodiment, the fiber termination adaptor 1710 includes a precision circular rim made for laser welded at its perimeter with an inner diameter of a hole in a side wall of the laser module sub-package 1800 (see FIG. 15) for hermetical sealing. The fiber termination adaptor 1710 further has its end face 1720 being laser welded with a lens which essentially the focus lens 1870 (see FIG. 15) for hermetic sealing. Optionally, the focus lens 1730 (FIG. 17) is also hermetically sealed around its perimeter in the lens structure 1860 (FIG. 15). Optionally, during the fiber coupling process, an active alignment process is performed to simultaneously align a focus lens 1730 (or 1860 in FIG. 15) to the fiber core 1701 such that the maximum amount of radiated power emitting from the laser diode through the focus lens 1730 is focused into the fiber 1701. Both the focus lens 1730 and fiber 1701 must be manipulated in the X, Y, Z linear direction within micron precision. In addition, the angular rotation of each axis must also be controlled during the alignment procedure. At the same time, the fiber assembly 1700 involving the fiber core, ferrule, fiber termination adaptor, requires a hermetically sealed assembly in addition to the good alignment between fiber and focus lens such that a coupling efficiency is kept greater than 60% or even greater than 80%.

FIG. 18 is a partial cross-sectional view of a fiber assembly according to another embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, in an alternative embodiment, a fiber assembly 1900 includes an end section having a ferrule 1902 enclosing the optical fiber 1901 therein except a small section of fiber core. On rest part (in the middle section) of the fiber assembly 1900, the optical fiber 1901 is protected by a fiber jacket. The ferrule 1902 is capped by a fiber termination adaptor 1910. In this embodiment, the fiber termination adaptor design is made to include a lens 1930 at its very end, allowing passive alignment of several relative positions between the lens 1930 and fiber core 1901. In the embodiment, the lens 1930 can be disposed at a concentricity position via mechanical references, eliminating the X, Y motion requirement of the lens. A precision spacer (not shown) allows the Z-axis position to be passively obtained to achieve desired alignment with sufficiently high coupling efficiency. The fiber termination adaptor 1910 has a precision rim for laser welded at its perimeter with the inner diameter of a hole in the side wall of the laser module 2080 (see FIG. 16). Optionally, the fiber assembly 1900 can be actively aligned, during its welding process with the laser module 2080, to the radiated power emitting from the laser diode with relaxed requirements. For example, the precision requirement can be relaxed to tens of microns instead of limiting to micron precision.

FIG. 19 is a perspective view of the light head member of FIG. 11 according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, a perspective view of the light head member 2300 includes a semi-open metal case 2301 with a slopped body 2310. A second end of the fiber assembly 1530 is configured to have the optical fiber 1535 to pass through an input port 2320 and be bended in parallel with the slopped body 2310. The slopped body 2310 further includes a reflecting semi-cone 2330 formed at a lower part where the optical fiber 1535 ended with a fiber head 1538 for guiding the laser beam into a surface of phosphor material 2350 with an angle. Optionally, the reflecting semi-cone 2330 is coated with a highly reflective material for white light.

In the embodiment, the phosphor material 2350 is disposed at a bottom region of the reflecting semi-cone 2330. The angle of the laser beam guided by the fiber head 1538 is relative to the surface of the phosphor material 2350. Optionally, the angle of the laser beam hitting the surface of phosphor can be set in a range from 30 degrees to 35 degrees. As the laser beam with blue emission is directed from the fiber head 1538 into a small spot 2355 in the surface of the phosphor material 2350, it excited the phosphor material 2350 to convert the received blue emission to a phosphor-excited emission with a longer wavelength (for example, a violet emission). Optionally, the spot size on the surface of the phosphor material 2350 is confined within 500 μm and even down to 50 μm. A mixing of the phosphor-excited emission with the blue emission of the laser beam forms a white light beam 2340 exiting (or substantially reflected by) upwards from the reflecting semi-cone 2330. Optionally, the phosphor material is mounted on a heatsink to conduct heat quickly away from the excited phosphor material when it is illuminated by a high-power laser emission. Optionally, a glass window material is placed overlying the slopped body and allow the white light beam to pass through to serve as a white light source. Optionally, the white light source is configured to produce substantially pure white light with strong luminance of flux in 250, 500, 1000, 3000, and 10,000 cd/mm².

In an embodiment, the fiber assembly 1530 integrated in the fiber-delivered laser induced white light system 1500 (see FIG. 11) can be made to be detachable so that applications of the system can be more flexible for maintenance. For example, a portion of failed parts can be easily replaced without disrupting the whole system. Optionally, referring to FIG. 11, the system 1500 can be provided with a detachable fiber termination adaptor (FTA) at an input port of the fiber assembly 1530 coupled with the main laser package 1510. Optionally, any place in the middle section of the fiber assembly 1530 can be selected for forming a fiber coupling joint using either mechanical fiber-to-fiber coupling mechanism or optical recoupling mechanism. FIG. 20 shows an exemplary diagram of a fiber coupling joint made by mechanical butt coupler according to an embodiment of the present invention. As shown, each of two attachable sections of the fiber assembly 1530 are respectively terminated with two connectors 2100 and 2200. Optionally, the connector 2100 is characterized by a total length L1 including a connector length L2 plus a boot 2130 and a connector size H. Each connector (2100) is coupled with the optical fiber (not explicitly shown) via a ferrule structure 2110 with one end being inserted into the connector 2100 with alignment to minimize fiber core offset, with eye-damaging prevention, and with dust protection. Another end of the ferrule is coupled first with a sleeve member 2120 before inserted into a bend-protection boot 2130. Two connectors 2100 and 2200 are mated together when they are respectively inserted into two entries of a mating adaptor 2300. The location of the coupling joint can be easily implemented into existing product.

In another embodiment, the fiber connector sets for forming the coupling joint can be made with lenses for optical recoupling. In this case, free-space optical elements are used for ensuring good optical coupling with substantially free of mechanical misalignment. Optionally, the optical-recoupling set includes window(s) for conveniently cleaning.

In yet another embodiment, referring to FIG. 11, the system 1500 can be provided with a detachable fiber termination adaptor (FTA) at an output port of the fiber assembly 1530 coupled with the light head member 1520. This option is substantially achieved like the FTA at the input port.

In another aspect, the present invention provides a fiber-delivered laser-induced dynamic light system. FIG. 21A is a block diagram of a dynamic light system based on fiber-delivered laser induced white light source according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, the dynamic light system includes at least a blue laser device 2511 driven by a laser driver 2501. Optionally, the laser driver 2501 can be separately integrated with other electronics involving various applications. Optionally, the blue laser device 2511 is a laser diode (LD) chip configured in a chip-on-submount structure with a gallium and nitrogen containing emitting region operating at a first wavelength in blue emission of a range of 395 nm to 490 nm. Optionally, the first wavelength of the blue emission is in a range of 395 nm to 425 nm. Optionally, the first wavelength of the blue emission is in a range of 425 nm to 490 nm. Driven by the laser driver 2501, the emitting region of the LD chip is configured to generate a laser electromagnetic radiation with an output power greater than 0.1 W, greater than 1 W, greater than 3 W, greater than 6 W, or greater than 10 W.

In an embodiment, the dynamic light system further includes one or more beam collimation optics and focus elements 2521 which are integrated in a laser sub-package with the at least one laser device 2511 for confining the laser electromagnetic radiation. For example, one collimator is needed to set in an optical path for handling the laser electromagnetic radiation out of the emitting region of the LD chip. Optionally, a reflecting mirror may be needed for redirecting the laser electromagnetic radiation to a different direction. Optionally, a beam splitter may be needed to split the laser electromagnetic radiation to two or more directions. Optionally, a focus lens is needed to couple at least a major portion of the beam of laser electromagnetic radiation to a pre-defined output port of the laser sub-package.

In the embodiment, the dynamic light system additionally includes a waveguide device 2531 that is coupled to the output port of the laser sub-package to receive the beam of laser electromagnetic radiation. Optionally, the waveguide device 2531 includes a fiber termination adaptor (FTA) in a fiber assembly holding a ferrule of an optical fiber. Optionally, the waveguide device 2531 is a semiconductor waveguide or a combination of an integrated semiconductor waveguide and a section of an optical fiber. Optionally, the optical fiber can be single mode fiber of multi-mode fiber with all kinds of optional fiber core structure characterized by different core diameters, gladding materials, and package types. Optionally, the fiber core diameters can be in a range selected from about 1 μm to 10 μm, about 10 μm to 50 μm, about 50 μm to 150 μm, about 150 μm to 500 μm, about 500 μm to 1 mm, or greater than 1 mm. Optionally, the focus lens is aligned with the optical fiber constrained with the FTA and output port of the laser sub-package and is able to couple the laser electromagnetic radiation substantially from a free space (exited the emitting region) to the optical fiber with a coupling efficiency greater than 60% or higher.

In the embodiment, the waveguide device 2531, e.g., a fiber assembly, can deliver the laser electromagnetic radiation up to an arbitrary length required for various applications at a remote destination. The dynamic light system further includes one or more dynamic beam controlling elements 2541 disposed at the remote destination and configured to receive the incoming laser electromagnetic radiation delivered by the waveguide device 2531. The dynamic beam controlling elements 2541 are configured to controllably direct, reflect, shut-off, amplify, attenuate, or modulate the electromagnetic radiation. Optionally, the dynamic beam controlling elements 2541 include a MEMS mirror for handling one beam or an array of MEMS mirrors to receive multiple beams split from a single beam exited from the waveguide device 2531. In the embodiment, the dynamic light system includes one or more wavelength converting elements 2551 to receive the beam of laser electromagnetic radiation directed by the dynamic beam controlling elements 2541. Optionally, the one or more wavelength converting elements 2551 includes a single phosphor plate. Optionally, the one or more wavelength converting elements 2551 includes a pixelated phosphor plate containing a plurality of small phosphor units. In the embodiment, the dynamic beam controlling elements 2541 is configured to create an excitation spot of the laser electromagnetic radiation onto the phosphor plate. Optionally, the pixel size can be formed in about 100 μm or less. The excitation spot can be limited within 50 μm or less. In particular, the excitation spot can be restricted to each phosphor unit, e.g., in a pixel in each unit-time and can be redirected to one or more pixels in subsequent one or more unit-times, depending on applications.

In the embodiment, the phosphor plate used as the wavelength converting element is comprised of a ceramic yttrium aluminum garnet (YAG) doped with Ce or a single crystal YAG doped with Ce or a powdered YAG comprising a binder material. The phosphor plate is configured to convert at least partially the incoming laser electromagnetic radiation of a first wavelength (e.g., in blue spectrum range) to a phosphor emission of a second wavelength. The second wavelength is longer than the first wavelength. Optionally, the second wavelength is in yellow spectrum range. Optionally, the phosphor plate has an optical conversion efficiency of greater than 50 lumen per optical watt, greater than 100 lumen per optical watt, greater than 200 lumen per optical watt, or greater than 300 lumen per optical watt. At least partially the laser electromagnetic radiation with a first wavelength and the phosphor emission with a second wavelength is mixed to produce a white light emission reflected out of the phosphor plate. Optionally, the white light emission has a luminance of 100 to 500 cd/mm², 500 to 1000 cd/mm² 1000 to 2000 cd/mm², 2000 to 5000 cd/mm², and greater than 5000 cd/mm². Since the white light emission can be generated under control by the dynamic beam controlling elements 2541 out of each single pixel of the phosphor plate dynamically in time, it forms a light source with a time-variable pattern which can further be projected to a far field. Optionally, the dynamic light system includes beam projection/delivery elements for handling the white light emission to become a useful white light source that is high power and dynamically controllable.

FIG. 21B is a block diagram of a dynamic light system based on fiber-delivered laser induced white light source according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, the dynamic light system includes a laser driver 2503 configured to drive multiple blue laser devices, e.g., a first blue laser device 2513, a second blue laser device 2514, and a third blue laser device 2515. Each laser device is substantially the same as one blue laser device 2511 described earlier. Optionally, the blue laser device is a laser diode (LD) chip configured in a chip-on-submount structure with a gallium and nitrogen containing emitting region operating at a first wavelength in blue emission of a range of 395 nm to 490 nm. Driven by the laser driver 2503, the emitting region of each laser device is to produce a laser electromagnetic radiation in blue emission. The dynamic light system further includes one or more beam coupling elements 2523 configured to combine all the laser electromagnetic radiation into a beam and guided or confined or coupled into an optical fiber. Optionally, the coupling of the laser electromagnetic radiation includes usage of one of more collimation lens, folding lens, beam splitters, focus lens. Optionally, the optical fiber is held in a fiber termination adaptor (FTA) 2533, in which the fiber is subjected to an active or passive alignment process to align with the focus lens so that the laser electromagnetic radiation can be coupled into the fiber core with substantially high coupling efficiency, e.g., at least >60% or even >80%. The optical fiber 2533 can be used to deliver the laser electromagnetic radiation to a remote destination up to a long distance with flexible layout for various applications.

Optionally, at a distal end of the optical fiber 2533, a dynamic beam controlling element(s) 2543 can be disposed and configured to incorporate the incoming laser electromagnetic radiation and redirect it as a beam to various directions with a pre-programmed manner. Each redirected beam can be collimated, shaped, or confined, or modulated. Optionally, the dynamic controlling element 2543 is a MEMS mirror that is fully controlled by a controller (not shown in the figure). Optionally, the controller is also used for controlling the laser driver 2503.

Optionally, a wavelength converting element 2553 can be included at a pre-set distance to receive the redirected beam of laser electromagnetic radiation with a specific angle of incidence between a propagation direction of the beam and a direction parallel to a surface of the wavelength converting element 2553. Optionally, the wavelength converting element 2553 is a phosphor material. Optionally, the phosphor material is configured to be a single surface plate or a pixelate plate containing multiple phosphor pixels arranged in a matrix array yet mutually separated from each other. Each phosphor pixel may be formed into a size smaller than 100 μm or even smaller than 50 μm. The setup of the phosphor plate at a certain distance from the dynamic controlling element 2543 and angular relation allows the beam of laser electromagnetic radiation to land in an excitation spot within each pixel. Optionally, each excitation spot can be as small as 25 μm to 50 μm.

Similar to the embodiment described earlier, the phosphor plate comprises a material that absorbs the incoming laser electromagnetic radiation of a first wavelength in a blue spectrum range and converts to a phosphor emission with a second wavelength longer than the first wavelength (e.g., in a yellow spectrum range). Out of the excitation spot, the phosphor emission of the second wavelength is partially mixed with the laser electromagnetic radiation with the first wavelength to produce a white light emission. In some embodiments, the white light emission has a luminance of 100 to 500 cd/mm², 500 to 1000 cd/mm², 1000 to 2000 cd/mm², 2000 to 5000 cd/mm², and greater than 5000 cd/mm², especially when the dynamic light system includes high-power laser generated by multiple laser diode devices for inducing the phosphor emission.

Additionally, the dynamic light system includes one or more secondary optical elements 2563 to further process, guide, shape, project the white light emission exited the phosphor plate. Since the dynamic beam controlling element 2543 is configured to control angle and strength of each redirected beam to different pixels on the phosphor plate, a dynamic light source can be formed based on the white light emission dynamically controlled by the system. Many applications can be implemented using this dynamic light system.

FIG. 22 is a block diagram of a dynamic light system based on fiber-delivered laser-induced white light source according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, a dynamic light system 2400 is made of laser diode unit (LDU) and a dynamic phosphor unit (DPU) mutually connected with an optical fiber or a waveguide. Each of the LDU and the DPU is respectively made of multiple elements. The LDU is made of multiple lasers (LDs) that generate blue laser light. The blue laser light is then optically conditioned by a collimating lens (C) or additional optical elements generating a high-power blue laser beam. Along an optical path the blue laser beam is then coupled via a fiber-terminated adaptor (FTA) to the optical fiber. The blue laser beam is guided by the optical fiber to the DPU. From the optical fiber, the blue laser beam enters the DPU. Upon entering the DPU the blue laser beam is collimated by optical lens and then directed to a MEMS mirror (MM). The MEMS mirror (MM) deflects the laser beam in desirable directions. Typically, the deflected laser beam from MEMS mirror (MM) is focused by another optical lens (O) to keep it collimated. Deflecting laser beam in different directions enables scanning of the laser beam over predefined area on a phosphor surface (PP). When the blue laser beam lands on a spot of phosphor (PP) it gets converted into a white light beam. Optionally, the phosphor (PP) is disposed on top of a heat sink as large amount of heat may be generated as the blue laser beam lands on the phosphor surface to excite the PP for emitting a spectrum with wavelengths longer than that of the blue laser beam. Finally, the white light beam emanating from phosphor surface is collected by secondary optics (SO) and projected into far field. The size of the white light beam is determined by the size of the blue laser beam, which in turns is defined by optics in the system 2400. Optionally, tilting of the MEMS mirror (MM) is controlled by an electronic circuit called MEMS driver. Also, a generation of the blue laser beam is controlled by a different electronic circuit called laser diode driver. Synchronization between these two drivers is important for proper functioning of the system 2400 and that is achieved via a MCU (microcontroller chip). A combination of these two drivers forms an electrical control unit (ECU) which includes an interface to receive control signals for the system 2400.

The role of a laser diode unit (LDU) is to generate high power blue laser light up to several Watts (6 W, 12 W, 15 W, etc.). The blue laser light is generated by multiple GaN-based LD chips. Blue light generated by one LDU is focused and guided by an optical fiber to one DPU. The DPU manages further the blue light beam by moving it and scanning a phosphor which is integral part of the DPU. In the phosphor the blue laser light is converted to a white light beam which is collected and projected by a secondary optics (SO) which is also integral part of the DPU.

In an embodiment, the white light beam projected by the secondary optics (SO) can be used to write or draw images by manipulating and controllably scan the laser beam over the phosphor or projecting high-intensity focused white light beam at the distance in different directions. The controlling and scanning of the laser beam can be achieved by use of the ECU.

In an embodiment, one or more beam conditioning optics in the LDU can be employed to couple the light emitted from one or more laser-diode emitting stripes into an optical fiber with efficiency greater than 60% or even greater than 80%.

In an embodiment, a shaped fiber tip on input side at the fiber terminated adaptor can be used to facilitate direct coupling of one or more stripes to fibers in high coupling efficiency. In the case of having multiple fibers at the input side, the fibers might be bundled or otherwise combined, e.g. by fusing the multiple fibers to a single light-guide. Similarly, the light output of multiple LDU's might be combined by bundling or fusing fibers, whether the laser light out of multiple LDs are beam conditioned or direct coupled to the fibers.

In another embodiment, the LDU includes an intermediate optics to direct light to photo-sensitive elements (e.g., photodiodes) for monitoring outgoing light and/or light returned from the DPU.

In another embodiment, multiple LD chips within individual LDUs might be driven independently to impact characteristics of the LDU and DPU emission, including average power, peak power, and spectral content. The emission output of a single LDU may be divided by free-space optics or a fiber splitter to pump multiple LDUs in one or multiple dynamic light systems.

In yet another embodiment, one LDU includes one or more solid-state wavelength and brightness converters. For example, a diode-laser pumped solid-state laser might be used to direct or fiber-coupled to pump one or more DPUs with brightness substantially higher than that of the diode-laser source.

In still another embodiment, an LDU might include multiple input pumps, conveyed to the LDU either by free-space propagation (e.g., co-packaged with the LDU) or waveguide (e.g., multiple fibers or semiconductor waveguide). Those pumps include multiple spectral and spatial profiles to manipulate the spectral and spatial profiles of the LDU emission.

FIG. 23 is a schematic diagram of a dynamic phosphor unit according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, at least the DPU includes several key components: a dynamic beam controlling element, optical lens, folding mirror(s), a pixelated or flat phosphor, and secondary optics. A blue laser light (from a LDU) enters the DPU via a fiber. Optionally, upon entering the DPU the blue laser light is collimated as a beam by an optical lens L1 and then directed to the dynamic beam controlling element which is controlled by a controller to handling the incoming beam by redirecting, deflecting, steering, shaping, magnifying or demagnifying, or modulating. Optionally, the dynamic beam controlling element is a MEMS mirror. Optionally, it can also be one selected from a digital light processing (DLP) chip, a digital mirror device (DMD), and a liquid crystal on silicon (LCOS) chip. The MEMS mirror deflects the beam in a desirable direction defined by tilting the MEMS mirror with an angle. Optionally, the MEMS mirror is configured to produce high deflection angles more than 10 degrees, low in power consumption of less than 100 mW, and high scan frequencies capable of producing HD resolution. Optionally, the MEMS mirror is configured to perform resonant operation for vector pointing and provide high reflectivity of >80% for high power operation. The deflected beam from the MEMS mirror is focused by another optical lens L2 to keep it collimated. After that the beam is deflected towards a phosphor by a folding mirror. When the blue laser beam lands on a spot of the phosphor it gets converted into white light. Finally, a beam of white light emanating from the phosphor is collected by secondary optics and projected into far field.

Optionally, the DPU includes an optical path that embodies reflective or transmissive architecture. Optionally, the DPU includes one or more phosphors with different shapes and a flat surface. Optionally, the phosphor is configured to be pixelated with each pixel unit being in a dimension of as small as 100 μm in square or circular or other geometric shape. The pixelated phosphor provides high contrast capability for the laser-based dynamic light system. Optionally, the pixelated phosphor is made from crystal material. Optionally, the pixelated phosphor is made from sintered material. Optionally, the pixelated phosphor is made from powdered material. Optionally, the pixelated phosphor is made by a subtractive method using femtosecond laser and etching method. Optionally, the pixelated phosphor is made by an additive method using micromachining of frame, phosphor powder, and sintering by thermal heating. Optionally, the DPU includes a secondary optics with high collection efficiency for light projection from several meters to several hundred meters. Optionally, the DPU includes a secondary optics for small spot projection capability with several cm in far field.

Optionally, focal lenses and folding mirrors are used in the PDU to keep laser beam collimated and help land the laser beam on the phosphor. Optical parameters of these components are defined to keep a spot size of the beam small (typically 100 μm to 200 μm range). Scanning range on the phosphor is typically about 20 mm.

In one embodiment, the input light from the LDU is collimated by a single lens placed at a distance equal to one focal length from the fiber. The collimated light is then incident on the MEMS mirror. A second lens is placed between the MEMS mirror and the phosphor at a distance equal to that focal length from the phosphor. The lenses might be conventional spherical, aspheric, cylindrical or toric refractive optical components, or might affect beam conditioning by other means (e.g., diffraction, possibly using one or more micro-optic diffractive elements). In addition, one or more intermediate mirrors might be used to direct the light between the LDU output and the phosphor. In the case of multiple LDU inputs to a single DPU, multiple beam conditioning paths and/or MEMS mirrors might be included in a single DPU. Further, a single DPU might include multiple phosphors and multiple sets of secondary optics.

FIG. 24 is a perspective view of a MEMS mirror package according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, MEMS mirror 2610 is circular and it is made of silicon. The circular MEMS mirror 2610 gets tilted by electrostatic force that is created between the mirror and electrodes situated under the mirror. The MEMS mirror 2610 is packaged in a MEMS package 2600 that allows access of the light to the mirror via visor from the front side. A back side of the MEMS package 2600 is designed to provide electrical access to MEMS mirror 2610 for driving tilting of the mirror.

In an embodiment, the role of MEMS mirror is to deflect a blue laser beam and scan it over the phosphor in the predefined area that is called scanning range. By doing so, the white light from phosphor can be projected in different directions that are defined by MEMS controller that drives MEMS mirror. It is important to stress that laser beam needs to be collimated and small in size. The spot size of laser beam when reaching phosphor is typically in the range of 100 μm to 200 μm, but could be as low as 50 μm or as high as 500 μm, depending on application requirements. This is achieved by one or more beam-conditioning optics placed between the input form the LDU(s) and the target phosphor(s). In a preferred embodiment, beam conditioning is done by one or more optical lenses that are placed, by design, at critical points in the optical train to keep laser beam collimated.

In another embodiment, the MEMS mirror can be tilted (driven) in different ways depending on principle of operation. Optionally, the MEMS mirror is operated via electrostatic forces. Optionally, the MEMS mirror is operated via electromagnetic forces. In a case electrostatic force is used, the tilting of mirror is driven by applying a high voltage (up to 200 V) between the mirror and driving electrodes. In a case of electromagnetic force is used, the tilting of mirror is caused by driving current through a coil (several hundreds of mA) and creating electromagnetic force that moves mirror. MEMS mirrors based on either one of these two types of forces can be used in the DPU. Range of tilting/scanning angle is typically from 0 degree to 10 degree, or 0 degree to 20 degree, but could be as high as 0 degree to 30 degree. Optionally, the shape of the mirror is made a circular with a diameter in the order of several mm. The mirror might be flat or curved (e.g., spherical, aspheric, cylindrical or others) to contribute to beam conditioning between the LDU output and the phosphor in the DPU.

In yet another embodiment, the secondary optics is provided to collect the white light from a small phosphor plate (either flat or pixelated) and project it to a far field. Far field collection efficiency needs to be typically 50% at the distance of 25 m. The far field range is from 10 m to 100 m and focusing image in the same range is required. To achieve collection efficiency above 50% and focusing capability for the far field. Glass lens, plastic lens, and motorized focusing may be utilized.

In still another embodiment, the ECU of the dynamic light system is operated to control alignment and synchronization of the scanned laser beam with position and orientation of a pixelated phosphor chip. This type of alignment must be performed at least once when the opto-mechanical system is aligned and built or repeated in the system in the field if necessary. In a first example with one alignment during device fabrication, the system must be subsequently stable mechanically so that misalignment does not develop with changes of temperature, humidity, aging or other external factors. Such a system would require very stable components and packaging and it would require specialized tool and assembly method, increasing the cost of the system. An alternative involves repeated alignment of the system in the field which does not require very stable components and assembly technologies but can be more difficult to implement. It is highly preferable if the system would function without mechanical positioning of the key components (such as mechanical translation and rotation) and would rely on use of an electronic alignment scheme.

The electronic alignment relies on setting up MEMS scanned beam with the pixelated phosphor and laser pulse synchronization. The positioning of the scanned laser beam is monitored by a single photodetector, high resolution CMOS imager or thermal imager. Based on the misalignment detected, the scanner voltage or current (for electrostatic or electromagnetic scanners respectively) is adjusted while the alignment is monitored. This process is carried out along one axis—say, in column direction, called here y direction. Minor in-plane rotational misalignment can be corrected the same way by adjusting the scanner voltages or currents in x direction. The color point can be also monitored and tuned by right amount or by slight misalignment of the beam with the walls of pixelated phosphor. The full pixelated area can be monitored or only small area in the center of pixelated phosphor can be tracked followed by extrapolation over the full surface of the phosphor.

When the excitation beam is scanned over the structure that has phosphor pixels and walls or frames of different material, the reflected and scattered light intensity will vary depending on the part of the area covered by phosphor and walls illuminated by the beam at any instant of time. When the walls are more reflective than phosphor material and the light passes over the wall area, the overall and blue content of light intensity from pixelated phosphor will increase compared with the light intensity when the beam is purely over the phosphor area. When the walls are more absorbing than the phosphor, the opposite will happen, with the light intensities going through minima while the excitation light is partially over the walls.

Consequently, the light intensity variation during the scan can be detected even with the single photodetector, two photodetectors (one for total intensity and one for blue intensity) or alternatively with the imaging array. The photodetector does not have to be large when the demagnifying lens is used in front of detector to reduce a size of a scanned image. The algorithms can be applied to convert these modulations of the overall and/or blue light intensity to the degree of misalignment and corrected by tuning the voltages or currents of electrostatic or electromagnetic scanners respectively.

The alignment signal represented by variations of light intensities during the scans over phosphor with walls will be small increase or decrease (depending on whether the walls are reflective or absorbing compared with the phosphor surface with or without antireflective film) on top of significant light background. Intrinsically, it would have low signal/noise, but the signal will be relatively periodic and predictable and smart algorithms should be able to pull out the needed alignment data from it. The signal/noise data can be improved by averaging many scans instead of a single scan. The data required for scanning correction of misalignment is only the pixel positioning (two unknowns) which is corrected by two values of the biaxial scanner voltage or current, in addition to timing of the laser pulses, thus adequately deterministic.

After y axis is aligned electronically, x axis is aligned by tuning the laser trigger and pulse duration, effectively synchronizing light pulses with the display pixels in the second (x row) direction. This way, the process can be iterated with column and row alignments to achieve complete optical alignment electronically.

A good projection display lens or lens system collects most of the emitted light for high optical efficiency, but it cannot collect all light. This light, for example at high emission angles can be captured by a single photodetector or optical sensing array. The second option is to use the beam splitter to divert a small percentage (1-5%) of light emitted at and near the normal incident angle to the photodetector or the detector array. The large beam splitter would be required for the full array monitoring and that would force increase in phosphor-projection lens distance, thus negatively impacting light collection efficiency. When the alignment signal is collected directly without a beam splitter at high emission angles that are not collected by the large light collection (projection) lens, the optical efficiency is not decreased even by few percent. Consequently, the first option is preferable, even though it receives the emitted light at the extreme angles. Any projection system providing the high-power light beams or images must have safety measures to protect the vision of the users and observers. One possibility is to use light intensity as the monitor. In this situation, the photodetector can serve two functions—alignment monitor and safety monitor and no additional components would be required when the detector serves these multiple functions.

When the black top walls are used, the pixelated phosphor is heated more than with reflective walls, and optical efficiency is decreased. The side walls of pixelated phosphor should be preferably reflective to maximize the optical efficiency and having different wall tops would complicate the phosphor fabrication. The reflective wall tops are easier to fab and they reduce the thermal loads, but they shift the color gamut into blue. This problem can be handled by a narrow blue filter on at least one surface of the projection lens. The right level of absorption of blue light is selected so that the optimized color gamut is achieved for walls with top reflective surfaces.

When narrow light pulses are chosen to reduce optical crosstalk, then the power and optical efficiency of the system are reduced. Optionally, larger crosstalk may be allowed but minimized by deliberate optical distortions of the excitation beam done by beam shaping.

FIG. 25 is a schematic diagram of a multichip laser diode unit according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, a laser diode unit (LDU) employed in a dynamic light system (see FIG. 22) can be configured with multiple laser diode (LD) chips. In particular, the LDU 2700 includes a stepped platform 2708, laser emitting diodes 2702, lenses 2703 and 2704, folding mirrors 2705, and optical fiber 2731 coupled through a fiber termination adaptor 2730 to a focal lens 2720 mounted with a metal frame 2740. The multichip LDU 2700 further includes multiple pins 2701 for providing driving currents to each individual laser emitting diodes 2702.

In an embodiment, the stepped platform 2708 is designed to ensure placement of multiple laser emitting diodes 2702 at different spatial level to avoid optical interference between them. Each one of laser emitting diodes 2702 generates laser light that gets collimated and directed to the fiber 2731. Optionally, the collimation operation is also achieved using stepped collimating lens units (2703 and 2704). Optionally, the collimation operation is also achieved using stepped reflecting mirror units (2705). In a fiber all separate light beams are combined together to create a unified high-power light beam. Optionally, the multichip LDU 2700 embodies flexibility in a number of laser emitting diodes up to tens of laser emitters. Optionally, multiple spatial laser beams are coupled into a single fiber.

In an embodiment, individually the blue laser light emanates from one laser emitting diode 2702, gets collimated with lenses 2703 and 2704 which keep laser light focused, and then it is directed to the fiber 2731 by a folding mirror 2705 (and optionally by a focus lens 2720). When the blue laser beam gets to the fiber 2731 it may be combined with other laser beams coming from others of the multiple laser emitting diodes 2702 creating a high-power laser beam. Each blue laser beam from one individual laser emitting diode contributes to the power of final beam in a manner proportional to its own power. Optionally, each laser emitting diode is a chip on submount.

Optionally, the multichip LDU embodies flexibility in driving laser emitting diodes individually or connecting them in series. In both options a higher laser power will be achieved. Optionally, each individual laser emitting diode is selected prior to assembly of the LDU.

FIG. 26 shows an application of a fiber-delivered dynamic white light source for street lighting according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, the fiber-delivered white light source for street lighting includes a laser diode bank 2800 (containing one or more gallium and nitrogen containing laser diode chips) remotely disposed in a utility box on curbside or buried underground. A laser beam, substantially in blue emission in an embodiment, is delivered via an optical fiber 2806 from a bottom of a street light pole 2805 to its top where a phosphor member 2810 is set up. Optionally, a dynamic control unit can be added to redirect the laser beam with a desired control scheme. In the embodiment, the phosphor member 2810 is configured to receive the incident laser beam either directly delivered by the optical fiber or redirected through a dynamic control element to generate a phosphor emission that is characterized by a wavelength longer than that of the laser beam in blue emission. A mixture of the phosphor emission and the laser beam with blue emission generates a white light emission. Optionally, the white light emission at the top of the light pole is shaped or projected by one or more optic elements to become wide angled beams 2815 with a controllable pattern. Optionally, provided a certain height of the street light pole 2805, the wide-angled beams 2815 resulted a spread illumination region 2825 in an elongated shape along the street 2820. The wide spread angle of the illuminated region of such street light with 100× higher luminance allows 3-5× reduction in numbers of street poles for the whole street light system. Additionally, since the laser diode bank is remotely disposed on or under the ground, no lift would be needed to change the bulb. This would make replacement or maintenance cost of the light system much lower. Optionally, the dynamic controlling element can be driven by a microcontroller chip with preprogrammed control schemes to operate the street light based on specific custom-designed illumination setup, on-road projection plan, or sensor-feedback-controlled variation. It would make the street light smart, less expensive, without need of heavyweight electronics and power supply.

In an alternative embodiment, similar fiber-delivered white light source can be developed for bridge lighting wherein the laser diode bank 2800 can be disposed at two ends of the bridge on shoreline for easy access while each of all lighting elements disposed on bridge can be configured with a light head member containing a phosphor member 2810 to receive the lase electromagnetic radiation delivered by a waveguide transport element such as the optical fiber 2806 from the laser diode bank 2800. Multiple fibers can be used to respectively deliver laser from the laser diode bank 2800 to multiple different light head members. The laser delivered by the optical fiber reaches a surface of a phosphor member in each light head member to generate a phosphor emission for producing a white light emission for illumination. Optionally, optics design allows the spread illumination region 2825 corresponding to each phosphor member 2810 to be respectively configured based on the bridge dimension and curvature to achieve best illumination or decoration effects with the most economic arrangement of positions, angles, heights of the light head member containing the phosphor member 2810.

In yet another embodiment, similar white light sources can be developed for application of tunnel lighting, down-hole lighting, stadium lighting, and many other special lighting applications that can take advantages of remotely delivering ultra strong visible lighting via the fiber-delivered white light source.

FIG. 27 is a schematic diagram of a fiber-delivered dynamic white light system for auto light application according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown, the dynamic light system is utilized as an auto headlight. A laser module containing one or more laser diode devices 2910 can be disposed in the car by integrating with the whole car electronics system, which is fully protected to avoid damage or other laser safety issues. The laser beam generated by the laser module, for example, a blue laser emission with a wavelength in a range of 395 nm and 490 nm emitted from a gallium and nitrogen containing active region can be coupled into a fiber 2920 to flexibly delivered to two headlamp modules 2931 and 2932. As the laser beam exits the distal end of the fiber 2920 inside each of the two headlamp modules 2931 and 2932, it firstly is redirected by a dynamic beam controlling element (not explicitly shown in this exemplary view) such as MEMS mirror or the like to reach to a selected spot of a phosphor surface in real time with control. The blue laser emission induces a phosphor emission with another wavelength longer than the laser wavelength. A mixture of the phosphor emission with a partial portion of the blue laser emission produces a white light emission. Since the blue laser emission landed on the selected spot of the phosphor surface is controlled by the dynamic beam control element in the headlamp module, the white light emission resulted from the selected spot also varies under control to form a desired pattern. Mechanical and optical designs of the headlamp module provide a secondary optics for the white light emission to effectively amplify or enhance the projection with smart control. For example, the left headlight projection varies its angle and brightness to avoid interference to incoming vehicle. The right headlight projection may raise its height or change focal length for clearly viewing roadside sign. All other variations of smart use of the headlight based on the fiber-delivered laser-induced white light source can be implemented under the scope of the present disclosure.

In some embodiments the fiber delivered white light source could be used for data transmission from the light source to devices configured to receive the signal. For example, the laser based light source could be used for Li-Fi and visible light communication (VLC) applications to transmit at high data rates of greater than 1 Gb/s, greater than 5 Gb/s, greater than 10 Gb/s. greater than 50 Gb/s, or greater than 100 Gb/s. Such high data rates enable by used of the visible light spectrum with laser diodes could enable new capability for applications such as the internet of things (IOT), smart lighting, vehicle to vehicle communication, mobile machine communication, street lighting to vehicle communication, and many more. Additionally, the fiber delivered white light sources could be applied to LIDAR applications.

While the above is a full description of the specific embodiments, various modifications, alternative constructions and equivalents may be used. As an example, the packaged device can include any combination of elements described above, as well as outside of the present specification. Although the embodiments above have been described in terms of a laser diode, the methods and device structures can also be applied to other stimulated light emitting devices. Therefore, the above description and illustrations should not be taken as limiting the scope of the present invention which is defined by the appended claims. 

1.-15. (canceled)
 16. A fiber-delivered laser-induced dynamic light system comprising: a laser diode unit comprising one or more laser devices for generating a laser electromagnetic radiation with a blue emission in a range from 395 nm to 490 nm, one or more beam-conditioning optics for collimating the laser electromagnetic radiation, and a fiber terminal adaptor configured to couple the laser electromagnetic radiation to an optical fiber; a dynamic phosphor unit comprising a bi-directional MEMS mirror capable of scanning in an x and y direction, the MEMS mirror being configured to receive the laser electromagnetic radiation exited from the optical fiber and controllably deflect a beam of the laser electromagnetic radiation to desirable directions, a first optics sub-unit configured to focus deflected beam of laser electromagnetic radiation to a surface spot on a phosphor plate to produce a white light emission, and a second optics sub-unit configured to collect a white light emission from the phosphor plate and to shape and project the white light emission of a far field; and an electronics control unit comprising a laser diode driver and a MEMS driver mutually synchronized, the laser diode driver being configured to drive each of the multiple laser devices in the laser diode unit to generate the respective laser electromagnetic radiation, the MEMS driver being configured to control the MEMS mirror in the dynamic phosphor unit to scan the beam of laser electromagnetic radiation to various surface spots on the phosphor plate to produce various white light emissions respectively at various times.
 17. The dynamic light system of claim 16, wherein each of the one or more laser devices comprises a chip-on-submount laser diode (LD) chip having a gallium and nitrogen containing active stripe region operating in one wavelength selected from 395 nm to 425 nm wavelength range and 425 nm to 490 nm wavelength range.
 18. The dynamic light system of claim 16, wherein the one or more laser devices is configured to generate the laser electromagnetic radiation with an output power of greater than 0.1 W, greater than 1 W, greater than 3 W, greater than 6 W, or greater than 12 W.
 19. The dynamic light system of claim 16, wherein the one or more beam-conditioning optics comprise one or more collimation lenses and folding mirrors to respectively direct the laser electromagnetic radiation from each of the one or more laser devices to the fiber terminal adaptor.
 20. The dynamic light system of claim 19, wherein the one or more collimation lenses and folding mirrors are disposed on a stepped platform configured to align with different active stripe regions of the one or more laser devices without mutual interference.
 21. The dynamic light system of claim 16, wherein the fiber terminal adaptor is configured to at least hold an end section of an optical fiber to receive the laser electromagnetic radiation with a coupling efficiency greater than 60%.
 22. The dynamic light system of claim 21, wherein the fiber terminal adaptor is configured to hold multiple optical fibers respectively aligned with an individual beam of laser electromagnetic radiation from a respective one of the one or more laser devices and an additional optical fiber fused to the multiple optical fibers to receive a unified power greater than 3 W, greater than 6 W, or greater than 12 W, or greater than 20 W with a coupling efficiency greater than 60%.
 23. The dynamic light system of claim 16, wherein the MEMS mirror comprises a silicon material with a surface polished to deflect light and tilted by electrostatic force created by applying high voltage up to 200 V between the MEMS mirror and driving electrodes disposed beneath the MEMS mirror.
 24. The dynamic light system of claim 16, wherein the MEMS mirror comprises a silicon material with a surface polished to deflect light and tilted by electromagnetic force created by a driving current of several hundreds of mA through a coil.
 25. The dynamic light system of claim 16, wherein the MEMS mirror comprises a circular shape having a diameter of several millimeters and being tilted in a range from 0 degree to 30 degree.
 26. The dynamic light system of claim 25, further comprises a microcontroller configured with the electronics control unit to provide control voltages or control currents to drive the MEMS mirror according to a predetermined scanning scheme.
 27. The dynamic light system of claim 26, wherein the microcontroller is configured to control the laser diode driver in a laser emission control scheme that is synchronized with the predetermined scanning scheme.
 28. The dynamic light system of claim 16, wherein the first optics sub-unit comprises one or more free-space optical elements including one or more focal lenses configured to keep the laser beam collimated and a folding mirror to direct the laser beam to the phosphor plate while keeping a spot size in a range of 50 μm to 500 μm for the laser beam reaching the phosphor plate and scanning over the phosphor plate over a range in the x and y direction.
 29. The dynamic light system of claim 28, wherein the range in the x and y direction is greater than 5 mm and 5 mm, respectively, or greater than 10 mm and 10 mm, or greater than 20 mm and 20 mm.
 30. The dynamic light system of claim 28, wherein the first optics sub-unit comprises one or more diffraction or micro-optic diffractive elements for directing the laser beam to scan over the phosphor plate over a range in the x and y direction.
 31. The dynamic light system of claim 28, wherein the phosphor plate comprises an array of pixels, each pixel having a dimension less than 200 um, or less than 100 um, or less than 10 μm of an independently configured phosphor material.
 32. The dynamic light system of claim 31, wherein the phosphor material comprises a sintered ceramic yttrium aluminum garnet (YAG) doped with Ce or a single crystal YAG doped with Ce or a powdered YAG comprising a binder material, separated by a side wall of different material from pixel to pixel.
 33. The dynamic light system of claim 16, wherein the electronics control unit further comprises an electronic alignment sub-unit configured to set up the beam of laser electromagnetic radiation being scanned by the MEMS mirror over the array of pixels of the phosphor plate to be synchronized with laser emission from one or more laser devices.
 34. The dynamic light system of claim 33, wherein the electronic alignment sub-unit comprises a photodiode, a high-resolution CMOS imager, or a thermal imager to determine misalignment by monitoring light intensity variation due to position and color of the laser beam scanned over the phosphor plate, based on which a scan voltage or current can be adjusted to correct mainly axial misalignment and a laser trigger and pulse duration can be tuned to correct minorly in-plane rotational misalignment.
 35. The dynamic light system of claim 16, wherein the second optics sub-unit comprises at least a light collector and a light projector, wherein the white light emission respectively out of the phosphor plate is guided to a far field with light collection efficiency of least 50% at a distance of about 25 m away.
 36. The dynamic light system of claim 35, wherein the second optics sub-unit comprises at least glass lenses, plastic lenses, and motorized focusing elements configured to project the various white light emissions out of the phosphor plate in respective different times to the far field ranging from 10 m to 100 m to provide a dynamic image having a same focus range. 